Described herein is a coated building panel that comprises a side surface that is textured and exhibits a white and/or color. The building panel comprising an upper surface opposite a lower surface and a side surface extending between the upper surface and the lower surface, a coating applied to the side surface, the coating comprising an inorganic particle having a disk shape and an ionic dispersant comprising an ionic group that are present on a repeating unit and the ionic dispersant comprising at least two of the repeating units.

A method for coating a building panel, the method including applying a first coating fluid including an organic binder on a surface of the building panel to obtain at least one coating layer, and applying barrier components and photocatalytic particles, preferably TiO.sub.2, on the at least one coating layer. Also, such a building panel.

An automobile body includes an article to be coated and a multilayer coating film. The multilayer coating film includes: a colored coating film formed on the article to be coated and containing a white pigment; a glitter coating film formed on the colored coating film and containing a glitter pigment; and a clear coating film formed on the glitter coating film. A lightness L*45 based on a spectral reflectance attained when light I.sub.45 applied at an angle of 45 degrees with respect to a surface of the multilayer coating film is received at an angle of 45 degrees with respect to regularly-reflected light is 70 or more and 90 or less.

The invention relates to the field of oil and gas production, and more particularly to the production of protective anti-corrosive coatings suitable for use in aggressive downhole oil and gas production conditions exacerbated by corrosion factors, including the deposition of salts and paraffins. The coatings are provided to protect the inner surfaces of oil tubular goods; including tanks and reservoirs for storing oil, oil-containing fluids, water and other solutions and fluids. Another goal of the invented coating is to protect pipes against corrosion during the transportation of oil, water, chemical solutions and other fluids, as well as to be used as a repair composition for the ends, outside and inside chamfers and the first two non-working turns of the threaded portion of production tubing. The invention results in improved performance characteristics and permits the production of an anti-corrosive coating that better preserves the physical, mechanical and thermomechanical properties of a material after exposure to aggressive corrosive media under pressure and at an elevated temperature.

An anti-fog composition is provided that includes a water-soluble polymer and a colloidal dispersion. The hydrophilic solvent system includes water and a miscible organic solvent, with water being the majority by weight of the composition. A process for applying the composition to a substrate is also provided. The substrates include not only glass, but also polycarbonate. The composition is well suited for formation of an end user kit for applying such a film to a substrate. Such a kit includes a container for the composition, or a wipe wet with the composition. The container being a bottle, or a propellant filled aerosol canister. Upon the composition drying on the substrate, the anti-fog film is produced without resort to additional application processes.

The present application discloses a thermal insulation coating and a method for applying the same. Raw materials for preparing the thermal insulation coating includes PVDF resin, water-based epoxy resin solution, hollow glass microbead, ytterbium modified nano-powder, diluent, polyvinyl alcohol, titanium dioxide powder, rare earth, negative ion powder, and leveling agent.

The present application discloses a thermal insulation coating and a method for applying the same. Raw materials for preparing the thermal insulation coating includes PVDF resin, water-based epoxy resin solution, hollow glass microbead, ytterbium modified nano-powder, diluent, polyvinyl alcohol, titanium dioxide powder, rare earth, negative ion powder, and leveling agent.

A composition for coating an overhead conductor is disclosed comprising: (i) a reflective agent; (ii) a photocatalytic agent comprising 70 wt % anatase titanium dioxide (TiO.sub.2) having an average particle size (aps)100 nm; (iii) a polyorganosiloxane binder; and (iv) a superhydrophobic agent comprising either: surface functionalised silica nanoparticles, a functional polysiloxane or a polymethylsilsesquioxane.

A coating applied to an article which includes a pigment or a dispersion. The coating comprising an upper side and a lower side. The coating being applied to at least one surface of the article: and wherein the coating is formed from a monomer and a nanoparticle which have passed through a plasma such that a plasma polymerised coating have been formed.

A silicone coating film provided as a surface layer of an irradiated object exposed to ultraviolet irradiation, includes a silicone rubber as a base material and titanium oxide particles with an average particle size of less than 100 nm. A laminated structure includes a first layer including a silicone rubber as a base material, and a second layer laminated on the first layer, wherein the second layer is the silicone coating film.