A soil-resistant transfer sheet which includes, in the following order, a substrate sheet (a), a soil-resistant layer (b), a coating layer (c), and optionally an adhesive layer (d), wherein a surface of the soil-resistant layer, which reveals after the substrate sheet (a) is removed, has a contact angle with water of 100° or larger and a contact angle with hexadecane of 40° or larger; a process for producing a molded resin by in-mold labeling using the transfer sheet. The soil-resistant layer (b) is a layer obtained from a soil-resistant composition, and the coating layer (c) is a layer obtained from a polymerizable coating composition. The soil-resistant composition especially preferably is a perfluoropolyether urethane acrylate composition. Also disclosed is a process for producing the soil-resistant transfer sheet.

The present invention is a long gas barrier laminate including a base, a functional layer, a smoothing layer, and a gas barrier layer, the functional layer being stacked on one side of the base, the smoothing layer and the gas barrier layer being sequentially stacked on the other side of the base, and a coefficient of static friction between a surface of the functional layer that is situated opposite to the base and a surface of the gas barrier layer that is situated opposite to the base being 0.35 to 0.80; and a method for producing the long gas barrier laminate.

A system and method for applying a coating to a surface. The coating can include any typical coating, but in some examples includes a styrenated acrylic coating. The coating is first applied. Thereafter, a quick-set formula which includes a brine solution is applied atop the first coating. The quick-set formula sets the first coating. Thereafter, a second coating, or multiple coatings, can be applied atop the first coating. Due to the quick-set formula, the second coating can be applied in less than 15 minutes.

The present invention is a long gas barrier laminate including a base, a functional layer, a smoothing layer, and a gas barrier layer, the functional layer being stacked on one side of the base, the smoothing layer and the gas barrier layer being sequentially stacked on the other side of the base, and a coefficient of static friction between a surface of the functional layer that is situated opposite to the base and a surface of the gas barrier layer that is situated opposite to the base being 0.35 to 0.80; and a method for producing the long gas barrier laminate.

A resin applied to underwater structures to enable biofouling growing thereon to be removed therefrom much easier than biofouling growing directly on the underwater structure. Adding antifungal properties to the resin enables the resin to prevent, or limit, the growth of biofouling thereon. The antifungal properties are provided by at least some subset of antifungal agents (e.g., copper) and antimicrobial agents (e.g., silver). The agents are mixed with plastic (e.g., polyethylene), melted, extruded into a solid form and then processed into an antifouling resin where the antifouling agent is embedded and integrated in the resin prior to application. The antifouling resin presents its antifouling properties immediately upon application and does not require gradual degradation to expose the active antifouling agents. The antifouling resin is thermal sprayed onto the underwater structure (an initial layer may be thermal sprayed onto an epoxy layer prior to curing to merge the two layers).