A method of applying to a crown surface of a piston, a heat shield material for forming a heat shield layer, is provided. The method includes masking the piston with a masking member, the masking member including a first part that covers at least part of a side surface of the piston with a first clearance between the side surface and the first part, and a second part that covers an outer circumferential part of the crown surface with a second clearance between the outer circumferential part and the second part, and applying the heat shield material, while the piston is masked.

Methods of treating a substrate, e.g., forming a coating on the substrate, are described. The method may include applying a solution comprising a multifunctional molecule or a multifunctional-polymer molecule to at least a portion of a surface of the substrate. The surface may comprise a metal or metal alloy and the multifunctional molecule or a multifunctional-polymer molecule may bond to the surface via at least one sulfur group of a plurality of sulfur groups of the multifunctional molecule. The method may include combining the multifunctional molecule with a polymer molecule to form the multifunctional polymer molecule before or after applying the solution. The polymer molecule may bond to an internal carbon group or a terminal sulfur group of the multifunctional molecule.

The method includes the steps of: applying atmospheric plasma on each area portion of the surface of a metal foil to be treated; increasing the surface free energy of the metal foil, making said surface free energy compatible with the surface tension of the varnish to be applied to the metal foil; applying a UV-cured varnish layer, which may be a oligomer, a monomer or a photo-initiator, having a solids content of 99% to 100% to the surface of the metal foil subjected to the atmospheric plasma; and curing the varnish layer using UV radiation to form a varnish coating adhered to the surface of the metal foil.

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.

This invention provides a polymer, which is preferably a polyether polymer. The polymer may be uses in coating compositions. Containers and other articles comprising the polymer and methods of making such containers and other articles are also provided. The invention further provides compositions including the polymer (e.g., powder coatings), which have utility in a variety of coating end uses, including, for example, valve and pipe coatings.

Coated articles and methods and systems for coating the articles are described herein. The methods and systems described herein include, but are not limited to, steps for actively or passively controlling the temperature during the coating process, steps for providing intimate contact between the substrate and the support holding the substrate in order to maximize energy transfer, and/or steps for preparing gradient coatings. Methods for depositing high molecular weight polymeric coatings, end-capped polymer coatings, coatings covalently bonded to the substrate or one another, metallic coatings, and/or multilayer coatings are also disclosed. Deposition of coatings can be accelerated and/or improved by applying an electrical potential and/or through the use of inert gases.

Methods for repairing the conventional physical barrier coating barrier on a component having a damaged portion. Applying a coating on the outer surface of the damaged portion of the component. The coating containing a reactive oxide. Initiating a reaction between the coating and the molten sulfates within the outer surface of the component. The reaction catalytically decomposes molten sulfates at the outer surface of the damaged portion of the component.

A prong style file fastener, and method of manufacturer, is disclosed which has a protective element to prevent damage to paper documents and personal injury. In one embodiment, the prongs of the fastener are covered with a powder coating which is melted thereon. In the case of the powdercoat covering, the production line uses a cam drive sprocket retractor system to release the line onto a takeup.

Provided is a manufacturing method in which a coated solder wire having a dense polysiloxane coating film that is uniformly provided over the entire surface of the solder wire can be efficiently obtained in a single process. A coated solder wire is obtained by a manufacturing method that includes; a radicalization step for forming a radicalized organic silicon compound by mixing a reaction gas that has been plasmatized under atmospheric pressure and an organic silicon compound that is introduced by way of a carrier gas, and radicalizing that organic silicon compound; a reaction area formation step for forming a reaction area that is defined by a helical gas flow and in which the radicalized organic silicon compound is uniformly dispersed; and a coating step for forming a 4 nm to 200 nm thick polysiloxane coating film on the surface of a solder wire by transporting a solder wire inside the reaction area and causing the radicalized organic silicon compound to react with metal on the surface of that solder wire.

A process for coating parylene onto a metal surface, such as a medical device, that has been textured by a series of laser pulses. The laser pulses can be overlapping or rastered. The textured portion of the metal surface and parylene coating can form a strong mechanical interlock. The bond created by using the laser texturing process can result in a cohesive failure of the parylene and not an adhesive failure of the bonding.