KR101051916B1 - Glass structure with silver nano powder - Google Patents

Abstract

It provides a glass structure attached with silver nano powder to utilize the properties of the glass itself, and to apply the silver nano function. The glass structure includes a porous carrier having fine pores attached to the substrate and a silver nanopowder supported on the porous carrier so that a portion of the glass structure is exposed to the substrate which is invisible to a certain melting point upon application of heat and decreases in viscosity and is exposed to a liquid state.

Glass structure, silver nano, porous carrier

Description

Glass structure attached nano silver powder

The present invention relates to a glass structure to which silver nanopowder is attached, and more particularly, to a glass structure to which silver nanopowder is attached in order to realize the characteristics of silver (Ag; Nano silver) on its surface.

Glass structures are one of the important materials for articles used throughout our lives. The glass structure is excellent in durability, chemically stable, and has no harm to human body. In addition, the transparent characteristics of the glass structure can be utilized in many fields such as building interior and exterior materials, vehicles, medical equipment, tableware, packaging containers. In particular, the use of heat-resistant glass structures that are harmless to the human body in recent well-being hot air has been increasing.

Silver (Ag) is an off-white metal with excellent electrical conductivity and reflectance to visible light, and excellent malleability and ductility, so it is easy to make silver or silver foil. In addition, silver is used as an industrial material and applied to numerous fields such as plating, paint, bimetal, deposition, dental materials, etc., and it has been used for dishes, jewelry, etc. to detect food toxicity or examine health status. Was used. In particular, the bacterium inhibits metabolism such as digestion, respiration, and sterilization, and silver ions (Ag ⁺ ) are known to inhibit the reproduction of bacteria.

Nanoparticles are nanometer (nm) level fine particles, and a certain volume of a material has a property of ensuring a large surface area in contact with other materials. These properties increase the rate of chemical reactions, allowing them to maximize the properties of the chemical composition of the material itself.

Silver nano is a nano-sized silver particle, and as described above, silver is a fine particle, and the material can exert its own physical properties by increasing the surface area that can react with other materials. Therefore, if silver nano is attached to the surface of the glass structure used in life will have the effect of antibacterial or sterilization. However, since glass has a smooth surface, high hardness, and brittleness, it is difficult to directly attach silver nano. In addition to the direct attachment method, a method of coating the surface of the glass structure by using a binder may be considered, but this makes the coating layer difficult to utilize the characteristics of the glass itself, and the silver nano powder is buried in the binder layer to properly perform the function of the silver nano. There is a problem that makes it impossible.

Therefore, the technical problem to be achieved by the present invention is to provide a glass structure with silver nano powder attached to utilize the properties of the glass itself, which can efficiently exhibit the function of silver nano.

The glass structure of the present invention for achieving the above technical problem is a substrate that is changed to a liquid state with a decrease in viscosity without a certain melting point when temperature is applied, a porous carrier having a fine pores attached to the substrate and supported on the porous carrier Contains silver nano powder.

In the glass structure of the present invention, the base material may have any one selected from among a flat type having a flat surface, a mold appearing in the shape of a mold, a porous type having a single cylindrical shape, or a porous type having a single body, or a combination of the above shapes. Can be done.

In a preferred glass structure of the present invention, the carrier may be attached to the surface of the substrate or embedded in a portion of the substrate and the remainder may be exposed to the surface of the substrate.

According to the glass structure of the present invention, the silver nano powder is directly attached to the surface of the glass structure in a state supported on the carrier to maintain the properties of the glass as it is, the silver nano powder is exposed to the outside to secure a large surface area that can react directly with the material The function of silver nano can be exhibited by doing this. Therefore, the present invention can be applied to all glass structures aimed at the function of silver nano.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described below may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. Embodiments of the present invention are provided to more fully explain the present invention to those skilled in the art.

Embodiments of the present invention will present a structure and a method for implementing the silver nano powder is supported on a carrier (carrier) attached to the surface of the glass structure. In addition, a method of utilizing the glass structure to which the silver nano powder is attached will be described.

1 is a cross-sectional view for conceptually explaining a glass structure according to the present invention.

Referring to FIG. 1, the glass structure of the present invention includes a substrate 10, a carrier 20 attached to the surface of the substrate 10, and a silver nano powder 30 supported on the carrier 20. The silver nano powder 30 is supported on the carrier 20 by an ion exchange method or a wet method. The carrier 20 on which the silver nanopowder 30 is supported is bonded to the surface of the substrate 10 by heat. As illustrated, a part of the carrier 20 may be buried in the substrate 10, and a portion of the carrier 20 may be exposed out of the substrate 10.

The base material 10 constituting the present invention is a hard material which is generally fragile, and has high quality at room temperature, so that there is no absorbency, water permeability, air permeability, and the like. However, when it reaches a certain temperature range by applying heat, it becomes a soft material such as rubber, and if it keeps applying heat, it may be in a fluid-like state. At this time, the base material 10 decreases in viscosity at a unique temperature according to the type and starts to change smoothly. The temperature at this time is called a glass transition temperature.

Typically, the substrate 10 may be applied to glass, and the general glass is composed of a mesh forming material constituting the tissue and a mesh tree oxide, which is an auxiliary material showing the special properties of the glass in combination therewith. Here, it is divided into silicate glass, borosilicate glass, phosphate glass and the like according to the mesh forming material, among which silicate glass is most widely used. In addition, the mesh tree oxide is a substance that imparts properties such as solubility, coloring, transparency, durability and conductivity of the glass, and corresponds to an oxide of an alkali metal such as sodium or potassium or an oxide of an alkaline earth metal such as magnesium, calcium or barium. . For example, soda (Na ₂ O), lime (CaO), magnesium oxide (MgO) and the like. In addition, lead oxide, aluminum oxide such as alumina (Al ₂ O ₃ ), etc. are also used as a tree oxide.

The carrier 20 is preferably made of a ceramic material such as zeolite, silica, alumina, zirconium phosphate, and may be a porous metal in some cases. That is, the porous material may be used as the carrier 20, and the silver nanopowder 30 applied to the present invention may be supported in the pupil formed in the carrier 20. At this time, since the silver nano powder 30 supported on the carrier 20 is not bound to the carrier 20, a part of the silver nano powder 30 may come out of the solution phase when it meets the solution.

The silver nano powder 30 is developed by nanotechnology, and refers to a colloidal state in which pure silver ions (Ag ⁺ ) having a purity of 99.9% or more are aggregated into several nanoparticles. Silver nano nanoparticles are 3nm to 5nm ultrafine particles are effective in antibacterial, bactericidal action. Specifically, by directly acting on harmful bacteria can dissolve the cell membrane, disrupt the electron transfer system of harmful bacteria to inhibit the metabolic activity to sterilize, it can block the reproduction of bacteria by dropping the fertility of the harmful bacteria. Accordingly, the harmful bacteria can be nearly sterilized by contacting the silver nano for 5 minutes or more, except in special cases. This bactericidal effect is not only applied to specific bacteria, but may also affect mold, house dust mites, Escherichia coli, and the like.

In addition, unlike the other antibacterial products, the silver nano powder 30 may exclude the problem of sustainability of high sterilization due to chemical composition, toxicity to the human body, and irritation. Specifically, the silver nano powder 30 is a fine particle of pure silver, so that it can continuously perform sterilization without volatility and elution. Since it is a natural material, it is harmless to the human body and can be used safely by children or the elderly.

2 is a cross-sectional view showing a method of manufacturing a glass structure of the present invention. The method proposed here is to attach the carrier 20 on which the silver nanopowder 30 is supported on the flat substrate 130. In this case, the glass structure refers to FIG. 1.

In general, when looking at the process of manufacturing glass, first, the raw materials suitable for glass molding are blended in a certain ratio, and the mixed raw materials are melted in a form that can be formed by heating to a temperature of at least 1500 ℃. Next, the molten raw material is divided into predetermined weights and molded into products through various molding machines. At this time, the melted compounding material is quenched and its structure becomes irregular due to the hard but essence of the liquid liquid.

As a result, the molded article quenched to have an irregular structure is subjected to an annealing process. That is, the quenched glass molding can be heated again to a constant temperature, which is an annealing point, and then cooled in a furnace in which the temperature is maintained to remove the non-uniform structure. The glass that has undergone the slow cooling process has transparency and strong strength. Processes applicable to the scope of the present invention may be various in addition to those described above.

Referring to FIG. 2, the substrate 130 is placed on the roller 140 disposed at regular intervals on the support 150, and is moved or stopped. Such a device may be arranged in a furnace for heating or cooling the substrate, the glass. In this case, the glass, which is the substrate 130, is divided into a soft layer 132 having flexibility and a hard layer 131 having no flexibility while being properly heated. In other words, the glass is gradually reduced in viscosity from the portion to which direct heat is applied, thereby providing flexibility. Therefore, the soft layer 132 having such flexibility becomes a portion to which the carrier 20 of the present invention can adhere to glass. In particular, since the carrier 20 is a porous material, it may be easily combined with the soft layer 132.

A device capable of spraying and attaching the carrier 20 carrying the silver nanopowder 30 is disposed at a predetermined distance from the substrate 130. The device is a storage unit 110 for storing the carrier 20 on which the silver nanopowder 30 is loaded, the pressing unit 100 for applying pressure to the carrier 20 stored in the storage unit 110 to push toward the substrate 130 ) And an injection unit 120 for spraying the carrier 20 on the substrate 130.

The soft layer 132 is embedded with a carrier 20 carrying the silver nanopowder 30 is injected by the pressure of the device, after which the carrier 20 is bonded to the substrate 130 in a predetermined condition. In this case, the injection unit 120 may move or rotate up, down, left, and right to supply the carrier 20 at an appropriate density according to the size, shape, or use of the flat substrate 130.

The carrier 20 embedded in the soft layer 132 is bonded to the soft layer 132 by heat. In other words, since the carrier 20 is a ceramic material such as zeolite, silica, alumina, zirconium phosphate, the carrier 20 is easily bonded by heat with the same ceramic material. Specifically, the carrier 20 is melted by heat while being in contact with the heated soft layer 132 to be fused with the soft layer 132, or a part of the soft layer 132 is fused by entering into the cavity of the carrier 20 to be fused. Can be.

The thickness of the soft layer 132 may vary depending on the type of glass and the carrier and the pressure applied to the pressing part 100. For example, if the combination of the carrier 20 and the soft layer 132 is easy to combine, the thickness of the soft layer 132 can be reduced. On the contrary, if the combination is rather difficult, the soft layer 132 can be thickened. The binding force can be increased. In addition, in order to maximize the ratio of the silver nano powder 30 included in the carrier 20, it is preferable to reduce the depth of the carrier 20 embedded in the soft layer 132.

In some cases, the carrier 20 of the present invention may be embedded in the soft layer 132 by free fall by its own weight without the pressing portion 100. That is, the carrier 20 can be combined with the soft layer even with a simple structure that does not include the pressing unit 100. In addition, the substrate 10 applied to the present invention is presented only the substrate 130 of the flat type, it is possible to apply the curved type or all possible forms according to the use of the glass structure in the scope of the present invention.

Hereinafter, a method of applying the glass structure of the present invention will be described with an example. Here, only a part of the field of application of the glass structure of the present invention is illustrated, so it may be applied to various fields within the scope of the present invention.

Figure 3 is a perspective view showing an example of the field of application of the glass structure of the present invention.

The application field presented here is to attach the carrier 20 on which the silver nanopowder 30 is supported on the substrate 200 for a mold. At this time, the description of the device for supplying the glass structure and the carrier 20 refer to FIGS.

According to FIG. 3, the substrate 200 for a mold may be applied to a process of manufacturing a container by fixing the substrate 200 by a separate mold 300 and bonding the substrate 200 by heat. The mold substrate 200 is divided into a hard layer 210 and a soft layer 212 as described above.

In addition, the manner in which the carrier 20 on which the silver nanopowder 30 is supported is attached to the mold substrate 200 which is a glass structure is the same as that of the flat substrate (130 of FIG. 2). At this time, the carrier 20 adjusts the pressure of the pressurizing part 100 of the device to be sprayed, and moves or rotates the sprayer 120 up, down, left, and right so as to have a suitable density and an appropriate depth on the surface of the substrate 20 for a mold. Can be attached.

The container made by the above method may be used as kitchen utensils, storage containers, baby bottles, and the like. In addition, it can be used as a medical product using a glass structure or used by a large number of people, such as a hospital, and can be applied to a structure in which several people come into contact, such as a door handle installed in a space where an infection is concerned, a faucet of a sink of a public restroom.

As mentioned above, although the present invention has been described in detail with reference to preferred embodiments, the present invention is not limited to the above embodiments, and various modifications may be made by those skilled in the art within the scope of the technical idea of the present invention. It is possible. For example, the application field of the present invention is only a mold substrate, but can be any shape that can be made of a glass structure, such as a cylindrical substrate made by the blowing technique, it is possible to form grooves, grooves or holes on the surface of the glass structure of various forms A glass structure can be formed. In addition, it can be applied to all structures requiring antibacterial and sterilization, in addition to the structures included in the tableware, medical supplies, and public places.

       1 is a cross-sectional view showing a glass structure to which the silver nanopowder of the present invention is attached.

2 is a cross-sectional view illustrating a method of manufacturing the glass structure of FIG. 1.

Figure 3 is a perspective view showing an example of the application of the glass structure of the present invention.

* Explanation of symbols for main parts of drawing *

10: base material 20: carrier

30: silver nano 100: pressing unit

110: storage unit 120: injection unit

130: flat substrate 131, 210: hard layer

132, 212: soft layer 140: roller

150: support 200: base material for mold

300: mold

Claims (3)

A substrate which is changed to a liquid state with a decrease in viscosity without a certain melting point when temperature is added; A porous carrier having fine pores attached to the substrate; And It includes a silver nano powder supported on the porous carrier, The carrier is partially embedded in the inside of the substrate and the rest of the glass structure is attached to the nano silver powder exposed on the surface of the substrate. The method of claim 1, wherein the base material has any one selected from among a flat type having a flat surface, a mold appearing in the shape of a mold, a porous type having an integral cylindrical shape, or a micropore, or a combination of the above shapes. A glass structure having silver nano powder attached thereto. delete

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