A method for obtaining a glazing includes a glass sheet covered, on one of its faces with electroconductive patterns having in at least one area, a so-called extra thickness area, a greater thickness than in the other areas, the method including depositing by screenprinting a first electroconductive layer forming patterns on one side of the glass sheet, then depositing by a digital printing technique, in the or each extra thickness area, a second electroconductive layer on the first layer while the latter is still wet, then a heat treatment step to cure the first and the second layer.

The present disclosure relates to a method for forming a glass structure having a metallized surface portion. The method may comprise forming a structure using a flowable first material, adapted to form a glass, which includes a metal component. The structure is then treated to remove substantially all solvents and organic components contained in the first flowable material. Finally, the structure is exposed to a bath of a metal salt during which nucleation occurs and a metallized surface coating is formed on at least a portion of an outer surface of the structure.

The present disclosure relates to a method for forming a glass structure having a metallized surface portion. The method may comprise forming a structure using a flowable first material, adapted to form a glass, which includes a metal component. The structure is then treated to remove substantially all solvents and organic components contained in the first flowable material. Finally, the structure is exposed to a bath of a metal salt during which nucleation occurs and a metallized surface coating is formed on at least a portion of an outer surface of the structure.

Provided is a metal film forming method which can form a metal film having excellent adhesion industrially advantageously and a metal film formed by using the method. A method of forming a metal film on a base includes an atomization step of atomizing a raw-material solution into a mist, in which the raw-material is prepared by dissolving or dispersing a metal in an organic solvent containing an oxidant, a chelating agent, or a protonic acid; a carrier-gas supply step of supplying a carrier gas to the mist; a mist supply step of supplying the mist onto the base using the carrier gas; and a metal-film formation step of forming the metal film on part or all of a surface of the base to causing the mist to thermally react.

Provided is a metal film forming method which can form a metal film having excellent adhesion industrially advantageously and a metal film formed by using the method. A method of forming a metal film on a base includes an atomization step of atomizing a raw-material solution into a mist, in which the raw-material is prepared by dissolving or dispersing a metal in an organic solvent containing an oxidant, a chelating agent, or a protonic acid; a carrier-gas supply step of supplying a carrier gas to the mist; a mist supply step of supplying the mist onto the base using the carrier gas; and a metal-film formation step of forming the metal film on part or all of a surface of the base to causing the mist to thermally react.

An anti-fog glass includes a glass body configured as a single layer or a multilayer stack; an active anti-fog layer disposed on the glass body and heating up when being provided with power; and a passive anti-fog layer disposed on the glass body and inhibiting fog from forming on the passive anti-fog layer. The passive anti-fog layer is a super hydrophobic coating and/or hydrophilic coating. Both the active anti-fog layer and the passive anti-fog layer are simultaneously disposed on the glass body to inhibit fog from forming. In this way, in a region of the glass body not covered by the active anti-fog layer, the anti-fog function is achieved by the passive anti-fog layer to a certain degree; in addition, in a region where the passive anti-fog layer itself cannot provide a desired anti-fog level, the active anti-fog layer together with the passive anti-fog layer provide a better anti-fog effect.

The present invention discloses a method for electroless plating of a metal or metal alloy onto a metal or a metal alloy structure comprising a metal such as molybdenum or titanium and alloys containing such metals. The method comprises the steps of activation, treatment in an aqueous solution comprising at least one nitrogen-containing compound or a hydroxy carboxylic acid and electroless plating of a metal or metal alloy.

The present invention discloses a method for electroless plating of a metal or metal alloy onto a metal or a metal alloy structure comprising a metal such as molybdenum or titanium and alloys containing such metals. The method comprises the steps of activation, treatment in an aqueous solution comprising at least one nitrogen-containing compound or a hydroxy carboxylic acid and electroless plating of a metal or metal alloy.

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 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.