Abstract: A method for coating a substrate is disclosed. The method includes applying a coating to a surface of the substrate and heating the applied coating and a first portion of the substrate. The first portion includes the surface of the substrate and less than the entire substrate. The method further includes cooling the applied coating and the first portion.

Abstract: A method of forming a composite overlay compound on a substrate includes forming a mixture including at least one component from a first group of component materials including titanium, chrome, tungsten, vanadium, niobium, and molybdenum. The mixture also includes at least one component from a second group of component materials including carbon and boron, and the mixture further includes at least one component from a third group of component materials including silicon, nickel, and manganese. The mixture of selected component materials is then applied to a substrate material to form an overlay compound on the substrate material. The overlay compound is fused to the substrate to form a metallurgical bond between the substrate material and the overlay compound.

Abstract: A component subjected to one or more of rolling, sliding, abrasion and bending contacts is disclosed. The component has a surface and functionally graded material (FGM) thermally sprayed on the surface to form an FGM coating. The FGM coating has a thickness and a plurality of material compositions. The FGM coating also has a plurality of elastic modulus profiles. Each elastic modulus profile consists of a plurality of elastic modulii at a plurality of corresponding points within that thickness. The elastic modulii are in the range from about 28 Mpsi to about 60 Mpsi. Optionally, there is also a plurality of carbon content profiles.

Abstract: A method for applying a functionally gradient coating on a component, having a surface and subjected to one or more of rolling, sliding, abrasion and bending contacts, including the step of thermally spraying a functionally gradient material (FGM) on said surface that forms an FGM coating, said FGM coating having a thickness, a plurality of material compositions and a plurality of elastic modulus profiles. Each elastic modulus profile consists of a plurality of elastic modulii at a plurality of corresponding points within that thickness. The elastic modulii are in the range from about 28 Mpsi to about 60 Mpsi. Optionally, there is also a plurality of carbon content profiles.

Abstract: A carbon coated metal powder depositable by thermal spray techniques to form a metal coating is disclosed. The carbon coated metal powder has a composition comprising a metal powder and carbon adhered to the metal powder. The metal powder is coated with carbon to form a carbon coated metal powder. The carbon coated metal powder, after being thermally sprayed on to a substrate and after being formed into a metal coating on the substrate, has an oxygen content at least 20% by weight less than the oxygen content in the carbon coated metal powder prior to being thermally sprayed.

Abstract: A self-lubricating and wear resistant valve/valve guide combination for an engine includes a self-lubricating coating deposited on one of (a) the inner surface of the valve guide, or (b) the outer surface of the valve stem. A wear-resistant coating deposited on one of (a) the outer surface of the valve stem when the self-lubricating coating is deposited on the inner surface of the valve guide, or (b) the inner surface of the valve guide when the self-lubricating coating is deposited on the outer surface of the valve stem. The self-lubricating coating has a composition, by weight, consisting essentially of, (a) a first component, comprising, a metal-bonded chromium carbide in the range of about 60% to about 80%, (b) a second component, comprising, a soft noble metal in the range of about 1% to about 20%, and (c) a third component, comprising, a metal fluoride eutectic in the range of about 5 to about 20%.

Abstract: A process for reducing oxygen content in thermally sprayed metal coatings comprises the following steps. A metal powder is provided. The metal powder has a particle size in the range of from about 10 .mu.m to about 500 .mu.m. Carbon is adhered and coated to the metal powder to form a carbon coated metal powder. The carbon is present in the range of from about 0.1% to about 2.0% by weight of the carbon coated metal powder. The carbon coated metal powder is thermally sprayed onto a substrate and a metal coating is deposited on the substrate. The metal coating has a lower oxygen content compared to the oxygen content of the carbon coated metal powder.

Abstract: A method for reducing oxygen content in metal coatings deposited by gas stabilized plasma spray techniques comprises the following steps. A metal powder is provided. Carbon is adhered and coated to the metal powder and a carbon coated metal powder is formed. A primary gas is provided to a plasma spray gun at a flow rate in the range of about 30-80 liter/min. A carrier gas is also provided to the plasma spray gun at a flow rate in the range of about 4-8 liter/min. The carbon coated metal powder is provided to the plasma gun at a flow rate in the range of about 30-85 gms/min. The plasma spray gun is positioned at a stand-off distance in the range of about 100-175 mm from a substrate. The plasma spray gun is energized with power in the range of about 28-42 kW. The carbon coated metal powder is sprayed onto the substrate and a metal coating having an oxygen content at least 20% by weight less than an oxygen content of the metal powder, is deposited.

Abstract: A process for applying a uniformly adherent protective tantalum oxide coating on a portion of a ceramic glow plug for protecting the glow plug against the corrosive/erosive environment generated by the burning of alternative fuels in a diesel engine. The coating is tantalum oxide deposited on a silicon nitride glow plug by plasma spray deposition techniques.

Abstract: A flowable slurry comprising powder matrix particles and reinforcing particles is pumped, under pressure, through an atomizing nozzle to form discrete droplets containing reinforcing particles coated with the powder matrix particles The discrete droplets are suspended in an elevated temperature environment for a sufficient time to evaporate the water from the droplets and form nonreacted reinforced powder particles. The reinforced powder particles are nonagglomerated and are suitable for immediate use as powder for thermal spray coatings or for dry processed compacted structural components.