RU2553015C1 - Coated glass vessel - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: disclosed is a glass vessel, particularly a bottle, flask or jar, having a coating on the outer side, which includes at least a pair of layers, the first layer containing carbon nanotubes and/or graphene, and the second layer deposited on the first layer and made by electropainting with a liquid or powdered dye, or by electrostatic deposition of a metal.

EFFECT: invention solves the task of making a glass vessel which is impervious to sun rays, capable of protecting a product from oxidation and decomposition, prolongs the shelf life of said product and preserves application properties and increases the durability of the vessel.

2 cl

Description

The invention relates to glass vessels and can be used in the production of artistic glass containers, tableware, decorative interior products, etc. in glass and other industries.

Glass is characterized by exceptional chemical resistance, therefore glass vessels are used as containers for food products, drinks, medicines, chemicals, perfumes, cosmetics, etc.

By design, glass containers are divided into narrow-necked bottles and wide-necked jars.

The disadvantage of glass containers is its transparency. For example, the sun's rays destroy the structure of wine placed in a transparent vessel. They are especially destructive for delicate white wines and champagne, although red wines also suffer - their color and taste change, the wine is intensely oxidized. In beer, under the influence of light, sulfur compounds are formed and a “light” flavor appears. Milk in a colorless bottle in the daylight quickly loses vitamin C. Light also negatively affects vitamins A, B6, etc. Vegetable oil ages and deteriorates when exposed to light. Cosmetic, perfumery compositions in transparent bottles in the light oxidize and lose their beneficial properties. Food and drinks in glass containers must be stored in dark rooms, basements, or special lightproof cabinets.

The invention solves the problem of creating a glass vessel, mainly a bottle, bottle, or can, not impervious to sunlight, able to protect the product placed in it from oxidation and destruction, extend the shelf life of this product and preserve its consumer properties, as well as increase the strength of the vessel.

The problem is solved in that a glass vessel is proposed, in particular a bottle, a can or a bottle, which has a coating on its outer side including at least a couple of layers, the first layer containing carbon nanotubes or graphene, and the second the layer is applied to the first layer by electrostatic staining with liquid or powder paints or by electrostatic deposition of a metal.

To obtain a coating of good quality, the first layer should contain such an amount of carbon nanotubes and / or graphene that provides its electrical conductivity of at least 10 ^-7 S / cm.

The proposed glass vessel is made as follows.

The preparation of a glass vessel is produced by blowing, or by press-blowing on a semiautomatic device or an automatic machine for manufacturing high-quality products by the blowing method (from pot furnaces), for which the following glass becomes used,% of the mass: SiO ₂ 77-78; CaO 6-8; R ₂ O 6-16.5.

Next, a first coating layer is applied to the surface of the vessel. This coating can be made from a solution of the modified polymer in a mixture with carbon nanotubes and / or graphene. To obtain a high-quality coating of the bottle as a whole, it is desirable that its first layer contain such an amount of carbon nanotubes that provides its electrical conductivity of at least 10 ^-7 S / cm.

A second layer is applied to the first coating layer of the vessel by painting the surface of the vessel in an electrostatic field, for example, with powder paint. To do this, the vessel is placed in a staining chamber, where powder paint is sprayed onto the cleaned product. In the process of spraying, particles of powder paint are electrically charged from an external source or electrified by friction. By the electric field, the particles of powder paint are transferred to the product to be painted, which has the opposite charge.

After powder paint is applied to the surface of the product, it is transferred to the polymerization chamber to polymerize the paint. For this, a polymerization furnace is used - a closed chamber, the internal working volume of which is heated to the temperature necessary for the polymerization process. The product to be painted is placed inside the polymerization chamber, where the layer of powder paint is heated to the state of its fusion. Melting of powder paints occurs in three stages: 1 - the powder is melted and passes into a viscous flow state; 2 - a monolithic layer is formed from melted powder particles; the surface to be painted is wetted with molten polymer. Upon further processing, carried out by curing (for thermoset materials) or cooling (for thermoplastic materials) of the polymer layer, a solid film is formed. As a result, a monolithic high-quality coating of a polymer film is formed on the outer surface of the glass vessel, characterized by uniformity, durability, opacity, and decorativeness.

According to the described technology, glass vessels of a wide variety of colors can be made.

A liquid coating material may also be used to obtain a second coating layer. In that case, during electrostatic painting, liquid paint material is sprayed in the painting chamber, while the smallest particles of paint are electrically charged from an external source. By the electric field, the particles of liquid paint are transferred to the product to be painted, which has the opposite charge, which is provided by the presence of carbon nanotubes in the first layer of the coating to be performed.

After applying the paint, the product is placed in a drying chamber to form a coating.

To obtain a metallized coating, the product after applying the first coating layer to it is placed in a bath with an electrolyte, where there is a process of electrostatic deposition of metal on the surface of the vessel with the formation of a metal film.

According to the described technology, any glass products can be made: bottles, bottles, cans, dishes, vases, interior items. The coating on the one hand performs a decorative function - the vessels can be painted in any color. On the other hand, the light-tight polymer film obtained on the surface of the vessel performs important utilitarian functions - it protects its contents from the effects of light and strengthens the vessel from the outside. Such hardening is especially important for products made of thin glass: glasses, jugs, vases, etc. Among other things, the polymer film in the case of a battle of vessels does not allow fragments to fly apart, while continuing to hold them together.

Since strength is of paramount importance among the indicators of operational reliability of glass containers - the bottles and cans mentioned here, the traditional technology for its manufacture provides for the application of protective and hardening coatings on its outer surface.

In this case, inorganic and organic coatings are used, which significantly change the properties of the glass surface and improve the mechanical characteristics of the products, in particular, increase the hydrophobicity of the surface, which reduces the softening effect of surface-active media and, above all, air moisture. At the same time, the surface of glassware is protected from the abrasive effects of various bodies and particles, which increases the strength of the glass under static and dynamic loads. For products hardened by surface coatings, the resistance to internal hydrostatic pressure increases by 10–20%, the pressure on the body - by 10–30%, and the height of the products –– up to 15%.

In the manufacture of glass containers according to traditional technology, a protective reinforcing coating of titanium oxide, or tin oxide, or zirconium oxide, or tin tetrachloride, or an organotin compound, or titanium tetraisopropylate, or other suitable compounds is applied to the surface of the product at the hot end of the conveyor. Further, using this technology, a protective hardening organic coating is applied to the outer surface of the product at the cold end of the annealing furnace, for example, of low molecular weight polyethylene, or modified polyethylene, or olefin polymer, or syntanol, or metaupon, or based on epoxy resin, or other suitable compounds .

Glass containers with a lightproof coating can be obtained without making significant changes to the traditional technology for its production. It is only necessary at the appropriate technological stages to add carbon nanotubes and / or graphene to the protective-hardening coating, and then apply a second coating layer.

If you do not violate the usual packaging technology, carbon nanotubes and / or graphene should be added to the protective-hardening coating applied at the cold end of the annealing furnace in an amount that ensures its electrical conductivity of at least 10 ^-7 S / cm. Thus, this protective reinforcing coating in terms used here will be the first layer of the proposed coating.

The second coating layer is obtained by electrostatically painting the surface of the container on top of the first coating layer or electrostatic deposition of metals, i.e. in this case, on top of the protective-reinforcing coating, in which carbon nanotubes and / or graphene are added, which is deposited on the cold end.

If the manufacturing technology of containers is changed, namely, if you refuse to apply a protective and reinforcing coating at the cold end, then carbon nanotubes and / or graphene should be added to the protective and reinforcing coating that is applied at the hot end of the conveyor. It can be made of titanium oxide, or tin oxide, or zirconium oxide, or tin tetrachloride, or an organotin compound, or titanium tetraisopropylate, etc., and contain carbon nanotubes and / or graphene. Thus, this protective reinforcing coating in terms used here will be the first layer of the proposed coating.

The second coating layer, obtained by coloring in an electrostatic field, can be applied, for example, with powder paints based on polyvinyl butyral, or polyethenes, or polyvinyl chloride, or polyamides, or epoxy resin, or polyester resin, or acrylate, or polyurethane.

Also, the second coating layer can be performed with liquid paints in an electrostatic field or by electrostatic deposition of metals.

The resulting coating has high protective and decorative properties. Obtaining such a coating on glass is provided by the presence of a first layer containing carbon nanotubes and / or graphene.

The proposed glass vessel, mainly a bottle, bottle or jar is not permeable to sunlight, is able to protect the product placed in it from destruction, has increased strength and high decorative properties. Glass vessels serving as containers, among other things, have a distinctive ability that allows you to distinguish certain products from a particular manufacturer or all products from this manufacturer from products from other manufacturers.

Claims (2)

1. A glass vessel, in particular a bottle, bottle or can, characterized in that on the outside it has a coating comprising at least a couple of layers, of which the first layer contains carbon nanotubes and / or graphene, and the second layer is deposited on the first layer and is made by electrostatic staining with liquid or powder paints or by electrostatic deposition of a metal. 2. The vessel according to claim 1, characterized in that the first coating contains such an amount of carbon nanotubes or graphene, which ensures its electrical conductivity of at least 10 ^-7 S / cm.