Ceramics are capable of reducing color irregularities and uneven coating, hard to dissolve into glaze, and excellent in fixation. A water-based paint contains a coloring material, first cellulose nanofibers having a lignin content of 20 to 40 mass % and a water retention of 150 to 300%, and second cellulose nanofibers having a higher viscosity compared to the first cellulose nanofibers, and the water-based paint has a B-type viscosity of 600 cps or higher. Ceramic ware or glassware or the like having painting made on a green body of which surface is formed of silicic acid or silicate compound as a main component, with the water-based paint.

A method for producing a reflector on a reflector base made of glass is provided. According to the method, a metal-containing coating fluid is deposited on a coating surface and subjected to a burning-in treatment at a temperature below a softening temperature of the glass forming the reflector layer. Deposition of the coating fluid proceeds using a contactless method by inkjet technology. This makes it possible to deposit a reflector layer in a reproducible way and with tight tolerances having a specified layer thickness, as well as to create clean edges without a printing block or similar device. The coating fluid is moved by a print head equipped with a plurality of nozzles and is movable in a movement plane relative to the coating surface. The coating fluid is sprayed onto the coating surface by the print head under pressure and in the form of droplets emerging from the nozzles.

A method for coating a glass article includes obtaining a glass article; selecting a coating including a fluorinated polyimide, and coating the glass article with the selected coating including the fluorinated polyimide. The fluorinated polyimide having a cohesive energy density less than or equal to 300 KJ/mol, and a glass transition temperature (T.sub.g) less than or equal to 625 K.

Provided is an apparatus for coating containers having an inlet where containers are handed over to the apparatus, and an outlet where containers leave the apparatus, having at least one vacuum device for producing a vacuum, having at least one treatment station for coating containers with a plasma, wherein the treatment stations are in fluid connection with the vacuum device and wherein the treatment stations have at least one treatment device into which is able to be introduced into a container, wherein the apparatus has a first and a second transport device for transporting containers, wherein the first transport device feeds the containers at least indirectly to a treatment station, wherein the first transport device is able to be switched off at least temporarily, resulting in the feeding of containers to the treatment station being interrupted, and the second transport device being an at least sectionally linear transport device.

According to one or more embodiments disclosed herein, a coated glass article may be made by a method that includes applying a water-based coating mixture onto at least a portion of a first surface of a glass article, and heating the water-based coating mixture to form a coating on the first surface of the glass article, where the coating includes metal oxide and polymer. The water-based coating mixture may include comprise water in an amount of at least 50% by weight of the water-based coating mixture, a polymer or polymer precursor, and a metal oxide precursor. The polymer or polymer precursor may be miscible in the water or may form an emulsion with the water. The metal oxide precursor may be miscible in the water or may form an emulsion with the water.

Provided is an apparatus for coating containers having an inlet where containers are handed over to the apparatus, and an outlet where containers leave the apparatus, having at least one vacuum device for producing a vacuum, having at least one treatment station for coating containers with a plasma, wherein the treatment stations are in fluid connection with the vacuum device and wherein the treatment stations have at least one treatment device into which is able to be introduced into a container, wherein the apparatus has a first and a second transport device for transporting containers, wherein the first transport device feeds the containers at least indirectly to a treatment station, wherein the first transport device is able to be switched off at least temporarily, resulting in the feeding of containers to the treatment station being interrupted, and the second transport device being an at least sectionally linear transport device.

Cleaning machine (20) of glass articles (G), comprising: a support (21) for supporting a glass article (G); and a heating device (22, 25) located in the vicinity of the support (21), at a distance therefrom, and configured to emit a heat flow (F, H) in the direction of a surface (G1) of the glass article (G) supported by the support (21).

The Invention discloses a manufacturing process for preventing shards of heat-resistant glassware from scattering, comprising the following steps: manufacturing a heat-resistant glass tube into corresponding product ware; performing annealing to remove stress; performing thermal shock testing; performing mechanical shock testing; performing mechanical spraying, and performing baking for 10 minutes to 30 minutes at 180 C. to 220 C. by using IR or in a baker. After this solution is used, shards of heat-resistant glassware are prevented from scattering.

According to one or more embodiments disclosed herein, a coated glass article may be made by a method that includes applying a water-based coating mixture onto at least a portion of a first surface of a glass article, and heating the water-based coating mixture to form a coating on the first surface of the glass article, where the coating includes metal oxide and polymer. The water-based coating mixture may include comprise water in an amount of at least 50% by weight of the water-based coating mixture, a polymer or polymer precursor, and a metal oxide precursor. The polymer or polymer precursor may be miscible in the water or may form an emulsion with the water. The metal oxide precursor may be miscible in the water or may form an emulsion with the water.

A hollow body includes a wall of glass which at least partially surrounds an interior volume of the hollow body. The wall of glass has a wall surface which has a surface region. At least in the surface region the wall surface has a content of N in a range from 0.3 to 10.0 at-%, and at least 5 at-% Si.