There is provided a manufacturing method of a Ni-based alloy repaired member having a repair piece formed at a damaged portion of a base material. The base material and the repair piece are made of a high precipitation-strengthened Ni-based alloy material. The manufacturing method includes the steps of: preprocessing a surface of the damaged portion; preparing a Ni-based alloy powder having a predetermined chemical composition; depositing a sprayed piece on the damaged portion by a high-speed collision spraying process using the Ni-based alloy powder; subjecting the sprayed piece to a predetermined heat treatment so that the sprayed piece is thermally refined to a softened sprayed piece; processing the softened sprayed piece into a shaped sprayed piece with a desired shape; and subjecting whole of the shaped sprayed piece and the base material to a predetermined heat treatment so that the shaped sprayed piece is thermally refined to the repair piece.

A sliding member of the present invention includes a base material and a coating layer that is formed on the base material. The coating layer includes a particle aggregate, and the particle aggregate contains two or more kinds of precipitation hardened copper alloy particles that have different compositions. The sliding member has high coating strength and superior wear resistance.

According to one embodiment, a semiconductor manufacturing apparatus member includes a base and a particle-resistant layer. The base includes a main portion and an alumite layer. The main portion includes aluminum. The alumite layer is provided at a front surface of the main portion. The particle-resistant layer is provided on the alumite layer and includes a polycrystalline ceramic. An Al purity of the main portion is 99.00% or more.

The disclosed invention includes articles having advantageous ceramic layers with a ceramic/metal intermediate layer that diminishes towards a pure metal core. Such articles have substantial use in unconventional, harsh environments.

The disclosed invention includes articles having advantageous ceramic layers with a ceramic/metal intermediate layer that diminishes towards a pure metal core. Such articles have substantial use in unconventional, harsh environments.

A metal-ceramic article and method for creating the same is disclosed in which the article has undergone machining to remove outer surface volume. The intermediate layer of the article includes a gradient of a metal and metal-ceramic that diminishes toward a metal core.

A method of preparing a graphene coating on a metal surface, the method includes: pretreating the metal surface of a metal sample; immersing, spraying or hang brushing the metal sample with the pretreated metal surface by using a graphene oxide aqueous solution, so that the grapheme oxide aqueous solution covers inner and outer surfaces of the metal sample; baking and drying the metal sample covered with the graphene oxide aqueous solution; performing a microwave reduction treatment on the baked and dried metal sample; taking out the microwave-reduced metal sample, cleaning the metal sample with a cleaning agent to obtain a metal coated with the graphene coating.

A method of manufacturing a laminate includes: forming a preprocessing coating on a surface of a substrate having insulating properties by accelerating the powdered material together with gas and spraying the powdered material in a solid phase onto the surface of the substrate, the powdered material including aluminum or an aluminum alloy as a main component; and forming a heat-treated coating having a surface with irregular asperities by heating a preprocessing laminate including the substrate and the preprocessing coating formed on the surface of the substrate.

The disclosure includes manufacturing a semimanufactured cylinder head (3) having a shielding curtain portion (16g) and spraying metal powder (P) onto an annular valve seat portion (16f) using a cold spray method to form a valve seat film (16b). The shielding curtain portion (16g) projects in an annular shape from an annular edge portion of an opening portion (16a) of an intake port (16) or an opening portion (17a) of an exhaust port (17) toward the center (C) of the port. The annular valve seat portion (16f) is located on an outer side of the port than the shielding curtain portion (16g).

A coating system configured to be applied to a thermal barrier coating of an article includes an infiltration coating configured to be applied to the thermal barrier coating. The infiltration coating infiltrates at least some pores of the thermal barrier coating. The infiltration coating decomposes within the at least some pores of the thermal barrier coating to coat a portion of the at least some pores of the thermal barrier coating. The infiltration coating reduces a porosity of the thermal barrier coating. The coating system also includes a reactive phase spray formulation coat configured to be applied to the thermal barrier coating. The reactive phase spray formulation coating reacts with dust deposits on the thermal barrier coating