Abstract: The invention provides a process for producing a high-precision reflector and its coating. A reflector is produced from a solid material using a material-removing process and is coated with a cold-light mirror layer.

Abstract: In the case of CVD methods, comprising PECVD and PICVD methods, the aim of the invention is to improve the impurity-free and, as far as possible, temporally and quantitatively precise feeding of process gases for the targeted layer systems. To this end, the invention provides a coating system and a method for coating articles with alternating layers, in the case of which process gases are introduced in an alternating fashion into a gas mixing point and mixed with a further gas and led to the reaction chamber, in which the deposition is carried out by producing a plasma.

Abstract: In order to improve the energy balance of an HID lamp, the quartz burner, preferably the inside thereof, is coated with a UV reflecting layer system by alternatingly applying amorphous thin layers made at least of titanium oxide and silicon oxide having the respective general stoichiometry TiOy and SiOx by means of a plasma impulse chemical vapor deposition (PICVD) method at a high power density and increased substrate temperatures ranging from 100° to 400° C., using small growth rates ranging from 1 nm/sec to 100 nm/sec so as to form an interference layer system having a thickness of less than 1200 nm and a minimized UV-active defective spot rate ranging from 0.1 to 1 percent.

Abstract: The invention relates to a process for producing a high-precision reflector and its coating. A reflector is produced from a solid material using a material-removing process and is coated with a cold-light mirror layer.

Abstract: The invention relates to layer systems having at least one layer comprising titanium aluminum oxide. The layer comprising titanium aluminum oxide may be either a functional layer—with or without interruption by an intermediate layer which is optically inactive—or a functional layer formed from a metal oxide which is interrupted by an intermediate layer comprising titanium aluminum oxide. The layer systems are structurally and thermally stable at operating temperatures of over 600° C. The layer systems may either comprise only one functional layer or may be a multilayer system, preferably an alternating layer system composed of functional layers with high and low refractive indices.

Abstract: The invention provides a process for producing a high-precision reflector and its coating. A reflector is produced from a solid material using a material-removing process and is coated with a cold-light mirror layer.

Abstract: The reflector for a light of higher power has a base body made of glass or glass ceramic and a protective jacket provided on the outer surface of the base body. The base body is formed with a receptacle for a light source, especially a gas discharge lamp, and an interior mirror surface for reflecting light. The protective jacket includes a mat or is a mat-shaped body, i.e. a woven or knit textile fabric of natural or synthetic material. Preferably it is a glass-fiber-reinforced mat. In addition to preventing splinters from flying around, the protective jacket advantageously also provides temperature equalization throughout the reflector. It also helps to prevent scattered light. The protective mat or jacket may be attached to the base body with an adhesive, such as a water glass.

Abstract: A method for production of a substrate having a patterned optical coating on a curved surface is provided. The method includes applying a masking to a sub-area of the curved surface, applying an optical coating using a vacuum deposition method, and removing the masking. A coated substrate, which can be produced in particular by the method described above, is also provided. The coated substrate includes a curved surface that is provided with at least one patterned optical coating. The at least one patterned optical coating is provided on at least one sub-area of the curved surface and is missing on at least one adjacent sub-area.

Abstract: The invention provides a process for producing at least one optical filter layer segment on a substrate. The process includes applying a masking comprising a resist layer on a surface of the substrate, depositing an optical filter layer on the surface and the resist layer by vacuum deposition, and removing the resist layer with a portion of the optical filter layer thereon from the surface. The deposition of the optical filter layer, at least at times, takes place at a temperature of over 150° C., preferably in a range from over 150° C. up to and including 400° C.

Abstract: A container having an at least partly transparent hollow body and a decoration is provided. The decoration includes at least one interior lining of the hollow body so that reactions between ingredients of a product situated in the container and constituents of the decoration are prevented.

Abstract: In order to improve the energy balance of an HID lamp, the quartz burner, preferably the inside thereof, is coated with a UV reflecting layer system by alternatingly applying amorphous thin layers made at least of titanium oxide and silicon oxide having the respective general stoichiometry TiOy and SiOx by means of a plasma impulse chemical vapor deposition (PICVD) method at a high power density and increased substrate temperatures ranging from 100° to 400° C., using small growth rates ranging from 1 nm/sec to 100 nm/sec so as to form an interference layer system having a thickness of less than 1200 nm and a minimized UV-active defective spot rate ranging from 0.1 to 1 percent.

Abstract: The invention relates to a process for producing an object which has optical layers. According to the invention such a process comprises the following process steps: To a substrate of plastic material several optical layers are applied; the optical layers are applied by means of a chemical plasma-impulse vaporization (PICVC).

Abstract: The reflector for a light of higher power has a base body made of glass or glass ceramic and a protective jacket provided on the outer surface of the base body. The base body is formed with a receptacle for a light source, especially a gas discharge lamp, and an interior mirror surface for reflecting light. The protective jacket includes a mat or is a mat-shaped body, i.e. a woven or knit textile fabric of natural or synthetic material. Preferably it is a glass-fiber-reinforced mat. In addition to preventing splinters from flying around, the protective jacket advantageously also provides temperature equalization throughout the reflector. It also helps to prevent scattered light. The protective mat or jacket may be attached to the base body with an adhesive, such as a water glass.

Abstract: A process for producing an object which has optical layers comprising the steps of applying optical layers to a substrate of plastic material wherein the optical layers are applied by means of a chemical plasma-impulse vaporization process (PICVD).

Abstract: The reflector for a light, which has a high-pressure gas discharge lamp, has an adherent polymeric coating extending over at least a portion of its outer surface. This polymeric coating contains at least one fluoro-polymer. The coating thickness is from 5 &mgr;m to 200 &mgr;m. A method of making the polymeric coating on the outer surface of the reflector includes powder coating the outer surface of the reflector with the at least one fluoro-polymer and subsequently heat after-treating the reflector with the powder coated outer surface. Alternatively the reflector is coated in a dipping or spraying process and then thermally after-treated. The coated reflector can be used in a headlight or an optical device for projecting data.