A photocurable coating composition includes 50 to 150 parts by weight of a urethane acrylate oligomer having a number average molecular weight of 1300 to 1700 g/mol and 9 functional groups, 50 to 150 parts by weight of an acrylate monomer, 10 to 15 parts by weight of a photoinitiator, and 1 to 3 parts by weight of a surfactant.

The method of producing a laminate of the present invention includes preparing a hard coat solution including an organic dye compound represented by following General Formula (1), a solvent, and a hard coat material; applying the hard coat solution on a primer layer which is provided over at least one surface of a lens substrate; and curing the hard coat solution applied on the primer layer to form a hard coat layer, in which the solvent is at least one type selected from 1-methoxy-2-propanol, butanol, and ethylene glycol monobutyl ether.

The present invention relates to a transfer polyester film. More particularly, the present invention relates to a transfer polyester film and a method for manufacturing the same, wherein the transfer polyester film has a coating layer with an excellent releasing property so that at the time of forming a hard coating layer in order to impart a surface gloss to an interior product, the transfer polyester film may be attached to a surface of the hard coating layer so as to allow the surface of the hard coating layer to be smoothly formed in a step of coating and curing a hard coating solution and may be removed after completely curing the hard coating layer.

The present disclosure generally relates to insulation articles including corrosion inhibitors and methods of producing the same are disclosed. In some embodiments, an article of manufacture comprising an insulation mat comprising an uncured combination of a plurality of randomly oriented fibers and a binder is provided. In further embodiments, the insulation mat extends between a first surface and a second surface, and a veil attached to the first surface and structured to inhibit physical movement of the cured combination through the veil is provided, as well as a metal sheet attached to the second surface by a water-containing adhesive contacting the metal sheet and the second surface, and a corrosion inhibitor composition deposited on the cured combination of the insulation mat, wherein the corrosion inhibitor composition is capable of modifying toward neutral a pH of the cured combination in contact with water from the water-containing adhesive.

Sealants and caulks (i.e., polymeric fillers) disclosed herein are polymeric fillers that comprises a polymeric material composition and one or more lipolytic enzymes dispersed within the polymeric material composition. In preferred embodiments, the polymeric material composition is an acrylic latex sealant such as that in the form of a caulk and the one or more lipolytic enzymes comprises a lipase such as, preferably, a triacylglycerol lipase. Advantageously, the one or more lipolytic enzymes of such sealants and caulks degrades lipid-containing contaminants and resulting lipid-containing stains that contain lipids. The degradation is a result of the ability of a lipolytic enzyme to catalyze a reaction on a lipid-containing substance (i.e., a substrate) to hydrolyze or move (e.g., intra-esterification) ester bonds of such lipid-containing substance. This lipid-degradation functionality at least partially inhibits the growth of such mold and mildew resulting from exposure to lipid-containing contaminants.

Sealants and caulks (i.e., polymeric fillers) disclosed herein are polymeric fillers that comprises a polymeric material composition and one or more lipolytic enzymes dispersed within the polymeric material composition. In preferred embodiments, the polymeric material composition is an acrylic latex sealant such as that in the form of a caulk and the one or more lipolytic enzymes comprises a lipase such as, preferably, a triacylglycerol lipase. Advantageously, the one or more lipolytic enzymes of such sealants and caulks degrades lipid-containing contaminants and resulting lipid-containing stains that contain lipids. The degradation is a result of the ability of a lipolytic enzyme to catalyze a reaction on a lipid-containing substance (i.e., a substrate) to hydrolyze or move (e.g., intra-esterification) ester bonds of such lipid-containing substance. This lipid-degradation functionality at least partially inhibits the growth of such mold and mildew resulting from exposure to lipid-containing contaminants.

A novel sublimation transfer paper is disclosed that incorporates a disclosed sublimation coating via a disclosed process for manufacturing the novel sublimation transfer paper. The novel sublimation transfer paper allows for consistent blooms for the sublimation inks, which leads to consistency of color. The novel sublimation paper also exhibits less cockling, which allows print heads to be closer to the novel sublimation transfer paper leading to the possibility of better print detail and the consumption of less ink. The novel sublimation transfer paper disclosed can be printed using sublimation dispersible inks having a water, oil, or solvent base with the substantially the same resulting color quality regardless of the ink base utilized.

Multi-layer anti-fouling coatings and methods of forming the same include a first biocidal layer formed on a surface. The first biocidal layer includes at least one biocidal biocide that kills a biofouling organism on contact with the first biocidal layer. A first biostatic layer is formed between the first biocidal layer and an external environment. The first biostatic layer includes at least one biostatic biocide that inhibits a biofouling organism from attaching to the first biostatic layer.

The present invention relates to an anti-bacterial and anti-dust coating for air ducting. In one embodiment, the anti-bacterial and anti-dust coating comprises: a polymer emulsion; a cross linking agent; a film forming agent; a filler and anti-dust agent; an anti-bacterial agent; hardener nanoparticles; a defoamer; and water. The anti-bacterial agent can be in powder or in liquid form. The coating can be applied on the inner surface of metal air ducting to reduce dust aggregation and prevent growth of bacteria, mold and mildew that causes stains and odors inside air ducting. With the aids of nanotechnology, various specific nanoparticles are added in the waterborne polymer emulsion to provide the anti-bacterial, anti-dust, anti-acid, anti-alkali, good flexibility and hardness for the coating. The product is also tested to be flame retardant and water resistance for increased safety in air ducts.

The invention relates to a coating composition for fabrics containing microfibers including a polymer and pigment within the microfibers and also to a method of coating fabrics.