Provided is a decorative film that can reduce temperature increase and exhibit excellent blackness compared to a case where a black layer prepared using a black pigment such as carbon black having a heat ray absorbing capability is employed. A decorative film according to an embodiment of the present disclosure includes a black layer containing a cyan pigment, a magenta pigment, and a yellow pigment, where the decorative film has an average transmittance of approximately 60% or greater for infrared light at a wavelength from 800 to 1800 nm, a light transmittance of approximately 30% or less at a wavelength of 750 nm, and a hue (a*) of approximately 0.80 or less in absolute value and a hue (b*) of approximately 1.2 or less in absolute value.

A coating composition including a polyester resin blend as a principal resin, the polyester resin blend containing a polyester resin having a glass transition temperature of higher than 40° C. and an acid value of less than 10 mg KOH/g and (B) a polyester resin having a glass transition. temperature of higher than 40° C. and an acid value of 10 mg KOH/g or more and less than 50 mg KOH/g, and (C) a curing agent. Alternatively, a coating composition containing a polyester resin, as a principal resin, having a glass transition temperature of 60° C. or higher, a resol-type phenol resin. and/or an amino resin as a curing agent, and an organic sulfonic acid-based catalyst and/or a phosphoric acid-based catalyst as a curing catalyst, in which a content of the curing catalyst is less than. 0.2 part by mass per 100 parts by mass of the principal resin. Provided is a coating composition that can manufacture a coated metal sheet and a drawn and ironed can, which have can making processability, substrate adhesion properties, and flavor sorption resistance all together.

The present invention relates to coating compositions and methods of forming catalyst-containing coatings on substrates for catalytic heater devices. The coatings are formed by a chemical grafting method, which chemically bonds the coating (and catalysts contained therein) to the substrate. The resulting coatings have high temperature resistance and inhibit or prevent catalyst migration to the substrate, thereby maintaining catalytic activity and desired temperatures over prolonged use.

The present invention relates to coating compositions and methods of forming catalyst-containing coatings on substrates for catalytic heater devices. The coatings are formed by a chemical grafting method, which chemically bonds the coating (and catalysts contained therein) to the substrate. The resulting coatings have high temperature resistance and inhibit or prevent catalyst migration to the substrate, thereby maintaining catalytic activity and desired temperatures over prolonged use.

As climate change and global energy consumption manifest in rising global temperatures and heat-islands, cooling living environments has become an urgent challenge. In developed settings, air-conditioning of buildings consumes energy, generates heat and releases greenhouse gases—exacerbating cooling needs. In developing regions, such as South Asia and sub-Saharan Africa, inadequate power infrastructure for cooling buildings has led to rising casualties during summers. Passive cooling technologies, which are sustainable alternatives to active cooling methods are provided. Systems and methods for passive radiative cooling coatings are provided as an effective approach for passive daytime radiative cooling of buildings.

As climate change and global energy consumption manifest in rising global temperatures and heat-islands, cooling living environments has become an urgent challenge. In developed settings, air-conditioning of buildings consumes energy, generates heat and releases greenhouse gases—exacerbating cooling needs. In developing regions, such as South Asia and sub-Saharan Africa, inadequate power infrastructure for cooling buildings has led to rising casualties during summers. Passive cooling technologies, which are sustainable alternatives to active cooling methods are provided. Systems and methods for passive radiative cooling coatings are provided as an effective approach for passive daytime radiative cooling of buildings.

Coating compositions for coating an oilfield operational component, and related methods, may include in some aspects a coating composition having a trifunctional silane, a silanol, and a filler. The coating composition may be applied to a surface of the oilfield operational component that is configured to be exposed to a fluid. The coating composition may be applied to at least partially cover or coat the surface. The coating composition may be configured to chemically bond with a cured primer composition that includes an epoxy.

Coating compositions for coating an oilfield operational component, and related methods, may include in some aspects a coating composition having a trifunctional silane, a silanol, and a filler. The coating composition may be applied to a surface of the oilfield operational component that is configured to be exposed to a fluid. The coating composition may be applied to at least partially cover or coat the surface. The coating composition may be configured to chemically bond with a cured primer composition that includes an epoxy.

The present invention relates to a composition for peelable-coating-film formation including an elastomer and an amino-modified silicone oil, wherein a film formed from the composition for peelable-coating-film formation has a breaking strength of F.sub.B (N/20 mm) in a tensile test and a coating film formed from the composition for peelable-coating-film formation on a surface of an SUS304 plate has a peel adhesive force of F.sub.G (N/20 mm) in peeling from the SUS304 plate, F.sub.B/F.sub.G being 1.5 or larger.

A water-based curable composition, for production of coatings having an antimicrobial property, contains at least one film-forming polymer, optionally at least one additive and/or at least one curing agent, and at least one up-conversion phosphor of the general formula (I): A.sub.1-x-y-zB*.sub.yB.sub.2SiO.sub.4:Ln.sup.1.sub.x,Ln.sup.2.sub.z. In the general formula (I), x=0.0001-0.0500; z=0.0000 or z=0.0001 to 0.3000 with the proviso that: y=x+z; A is selected from Mg, Ca, Sr and Ba; B is selected from Li, Na, K. Rb and Cs; B* is selected from Li, Na and K; and preferably B and B* are not the same. Additionally, Ln.sup.1 is selected from praseodymium (Pr), erbium (Er), and neodymium (Nd); and Ln.sup.2 is gadolinium (Gd). The phosphor, as a result of an aftertreatment, includes at least one material which has a band gap of greater than 6.0 electronvolts (eV) and is hydrolysis-stable.