A process for forming on a corrodible substrate a corrosion-resistant multi-ply coating comprising: (a) applying an aluminum-containing silicate slurry onto the surface of the substrate and heating the deposited slurry to form a cured composite of an aluminum-Containing silicate basecoat that is not electrically conductive, optionally repeating the aforementioned step to form a thicker multi-ply coating, (b) applying an initial solution of tri valent aluminum and phosphate ions (Al.sup.+3PO.sub.4) to the surface of said basecoat and heating the substrate that has thereon said solution to form a cured ply comprising a composite that is not electrically conductive; (c) mechanically working the surface of the composite to form a modified composite which is in electrically conductive form; and (d) applying to the surface of the modified composite an additional solution of divalent aluminum and phosphate ions (Al.sup.+3PO.sub.4), the composition of which may be the same as or different from said initial solution, and heating the modified conductive coated surface having thereon said additional solution under conditions which cure it to form said multi-ply coating which is not electrically conductive, a multi-ply coating prepared by the process, and an article coated with the multi-ply coating.

Described herein is a flame-retardant building panel comprising a body having a first major surface opposite a second major surface, an inorganic coating atop the first major surface, the inorganic coating being optically transparent and flame retardant and comprising a silicate compound; and wherein the inorganic flame retardant coating is substantially transparent such that the first major surface of the body is visible through the inorganic coating.

Described herein is a flame-retardant building panel comprising a body having a first major surface opposite a second major surface, an inorganic coating atop the first major surface, the inorganic coating being optically transparent and flame retardant and comprising a silicate compound; and wherein the inorganic flame retardant coating is substantially transparent such that the first major surface of the body is visible through the inorganic coating.

The invention relates to a coating composition, especially to a coating composition intended for thermal insulation of hot metals, which contains an aqueous solution of silicate and which consists of the first layer containing 35 to 71 volume percent of hollow glass spheres, 26 to 62 volume percent of an aqueous solution of potassium silicate, 1 to 3 volume percent of an adhesive additive, and 0.1 volume percent of a water glass stabilizer, and of at least one second layer containing 71 to 84.6 volume percent of hollow glass spheres, 9 to 22.6 volume percent of an aqueous solution of potassium silicate, 0.2 to 0.3 volume percent of an adhesive additive, 0.1 volume percent of a water glass stabilizer, 2 to 3 volume percent of cut glass fibres, and 1.7 to 3 volume percent of a styrene-acrylate dispersion. Method of application of the coating composition, especially method of application of the coating composition which consists of at least one layer containing an aqueous solution of silicate according to which, as the first step, the first layer containing 35 to 71 volume percent of hollow glass spheres, 26 to 62 volume percent of an aqueous solution of potassium silicate, 1 to 3 volume percent of an adhesive additive, and 0.1 volume percent of a water glass stabilizer is applied and then the second layer containing 71 to 84.6 volume percent of hollow glass spheres, 9 to 22.6 volume percent of an aqueous solution of potassium silicate, 0.2 to 0.3 volume percent of an adhesive additive, 0.1 volume percent of a water glass stabilizer, 2 to 3 volume percent of cut glass fibres, and 1.7 to 3 volume percent of a styrene-acrylate dispersion is applied onto the first layer.

The invention relates to a coating composition, especially to a coating composition intended for thermal insulation of hot metals, which contains an aqueous solution of silicate and which consists of the first layer containing 35 to 71 volume percent of hollow glass spheres, 26 to 62 volume percent of an aqueous solution of potassium silicate, 1 to 3 volume percent of an adhesive additive, and 0.1 volume percent of a water glass stabilizer, and of at least one second layer containing 71 to 84.6 volume percent of hollow glass spheres, 9 to 22.6 volume percent of an aqueous solution of potassium silicate, 0.2 to 0.3 volume percent of an adhesive additive, 0.1 volume percent of a water glass stabilizer, 2 to 3 volume percent of cut glass fibres, and 1.7 to 3 volume percent of a styrene-acrylate dispersion. Method of application of the coating composition, especially method of application of the coating composition which consists of at least one layer containing an aqueous solution of silicate according to which, as the first step, the first layer containing 35 to 71 volume percent of hollow glass spheres, 26 to 62 volume percent of an aqueous solution of potassium silicate, 1 to 3 volume percent of an adhesive additive, and 0.1 volume percent of a water glass stabilizer is applied and then the second layer containing 71 to 84.6 volume percent of hollow glass spheres, 9 to 22.6 volume percent of an aqueous solution of potassium silicate, 0.2 to 0.3 volume percent of an adhesive additive, 0.1 volume percent of a water glass stabilizer, 2 to 3 volume percent of cut glass fibres, and 1.7 to 3 volume percent of a styrene-acrylate dispersion is applied onto the first layer.

The present disclosure is directed to compositions and methods for coating, particularly protecting and optionally cleaning, metallic surfaces, and articles containing such surfaces; wherein the compositions include a zwitterionic polymer including pendant zwitterionic moieties, an inorganic silicate, and water.

The present disclosure is directed to compositions and methods for coating, particularly protecting and optionally cleaning, metallic surfaces, and articles containing such surfaces; wherein the compositions include a zwitterionic polymer including pendant zwitterionic moieties, an inorganic silicate, and water.

The disclosure relates to a field of functional coating technologies, and particularly to a durable inorganic super-hydrophilic paint, a preparation method and an application thereof. The durable inorganic super-hydrophilic paint includes the following preparation raw materials in percentage by mass: 30˜60% silicate, 5˜25% zinc oxide, 10˜40% water and 0.1˜5% wetting agent. The coating formed by a durable inorganic super-hydrophilic paint prepared by the method is a flat rigid coating, with good appearance, excellent antifouling self-cleaning and anti-microbial adhesion properties, long-term underwater stability and high mechanical strength. The paint may be applied to building external walls and home inner walls for its antifouling self-cleaning property and may be applied to a field of oil field and oil-water separation for its excellent underwater oleophobic property.

The present disclosure relates to a laminate and a method for preparing the same. The laminate comprises a substrate, a coating layer, and a water-repellent layer sequentially laminated, the coating layer comprises a first coating layer and a second coating layer laminated one or more times alternately, the first coating layer comprises at least one metal oxide selected from a group consisting of a lanthanide metal oxide, a transition metal oxide, and a composite metal oxide comprising lanthanum metal and transition metal, the second coating layer comprises an alkaline earth metal fluoride and a transition metal oxide.

The present disclosure relates to a laminate and a method for preparing the same. The laminate comprises a substrate, a coating layer, and a water-repellent layer sequentially laminated, the coating layer comprises a first coating layer and a second coating layer laminated one or more times alternately, the first coating layer comprises at least one metal oxide selected from a group consisting of a lanthanide metal oxide, a transition metal oxide, and a composite metal oxide comprising lanthanum metal and transition metal, the second coating layer comprises an alkaline earth metal fluoride and a transition metal oxide.