The present invention provides a preparation method of a zirconium-titanium-based alloy embedded aluminized layer, and relates to the technical field of metal surface modification. The preparation method provided by the invention comprises the following steps: putting a zirconium-titanium-based alloy and an aluminiferous penetrant into a mould from bottom to top in the sequence of a first penetrant layer, a first zirconium-titanium-based alloy, a second penetrant layer, a second zirconium-titanium-based alloy and a third penetrant layer, and compacting to obtain a mixed sample; sequentially covering the surface of the mixed sample with activated carbon powder and alkali metal halide, and then sequentially carrying out heat treatment and cooling to obtain a zirconium-titanium-based alloy embedded aluminized layer. The preparation method provided by the invention does not need to adopt a special heating furnace or carry out heat treatment under a vacuum condition in the actual application process, simplifies the operation process and the operation condition, has small technical difficulty and small equipment investment, and is suitable for large-scale production and application.

A method for preparing a seal assembly for a gas turbine engine, comprising a seal comprising a carbon material; and a seal seat positioned for rotation relative to the seal, wherein the method comprises the steps of: pre-filming a sealing surface of the seal seat with a carbon-based tribofilm; and assembling the seal seat relative to the seal in a gas turbine engine.

An inductor includes a magnetic base body including soft magnetic metal particles containing iron, first and second external electrodes provided on the magnetic base body, and an internal conductor provided in the magnetic base body, with one end thereof electrically connected to the first external electrode and the other end thereof electrically connected to the second external electrode, the internal conductor extending linearly from the first external electrode to the second external electrode in plan view. The magnetic base body is configured so that a peak intensity ratio is 2 or more between a peak intensity of a first peak and a peak intensity of a second peak in a Raman spectrum obtained by using an excitation laser with a wavelength of 488 nm. The first peak is around a wave number of 712 cm.sup.−1, and the second peak is around a wave number of 1320 cm.sup.−1.

A method of forming an activated coating composition is disclosed. The method includes providing (a) boron nitride, (b) carbon, (c) aluminum oxide and (d) a liquid carrier. Each of the boron nitride, carbon and aluminum oxide are in particulate form. The coating composition is activated to form an activated coating composition. The activated coating composition includes active components having from about 60.0 wt % to about 90.0 wt % boron nitride, from about 16 wt % to about 24 wt % carbon and from about 4 wt % to about 6 wt % aluminum oxide. A coating method, coated substrate and activated coating composition are also disclosed.

A powder applying apparatus includes a transport device, a powder supplier, and a squeegee. The transport device moves a sheet in a predetermined direction. The powder supplier supplies powder on a surface of the sheet. The squeegee has a distance from the sheet, and the powder supplier adjusts the thickness of powder supplied onto the surface of the sheet. The squeegee vibrates at a frequency of 2 kHz or more and 300 kHz or less.

A method for coating a metal based component surface wherein said metal based component has an inner and/or outer surface portion that is to be coated, and which surface portion comprises a carbide forming composition. A cavity having one or more cavity walls, wherein said at least one inner and/or outer surface portion forms at least a portion of said one or more cavity walls is provided, and a portion of the cavity is filled with diamond powder. Thereafter gas is removed from the interface between said diamond powder and said at least one inner and/or outer surface portion, and the cavity is subjected to a hot pressing process for a predetermined time at a predetermined pressure and a predetermined temperature such that said diamond powder diffusion bonds to said at least one one inner and/or outer surface portion. Finally at least a part of said diamond powder is removed from said at least one cavity.

A method of forming an activated coating composition is disclosed. The method includes providing (a) boron nitride, (b) carbon, (c) aluminum oxide and (d) a liquid carrier. Each of the boron nitride, carbon and aluminum oxide are in particulate form. The coating composition is activated to form an activated coating composition. The activated coating composition includes active components having from about 60.0 wt % to about 90.0 wt % boron nitride, from about 16 wt % to about 24 wt % carbon and from about 4 wt % to about 6 wt % aluminum oxide. A coating method, coated substrate and activated coating composition are also disclosed.

An electrical contact part comprising, a carrier substrate of a metallic material, a metallic coating applied to the carrier substrate, and a coating barrier material applied to the carrier substrate in a partial area of the carrier substrate, wherein the coating barrier material substantially prevents coating of the carrier substrate in the portion.

A deposition device includes: a generation chamber; a deposition chamber; a transfer tubing; a target; a stage; and a mask member. The target is disposed in the deposition chamber, has an irradiation surface to be irradiated with the aerosol injected from the nozzle, and causes the raw material particles to be charged to plasma by collision with the irradiation surface. The stage has a support surface that supports a base material, fine particles of the raw material particles produced by discharging of the charged raw material particles being deposited on the base material. The mask member is disposed in the deposition chamber, and inhibits raw material particles specularly reflected on the irradiation surface, of the raw material particles that have been collided with the irradiation surface, from reaching the stage.

A surface to be coated of a component is roughened by a laser. The roughened surface is coated by cold spraying. A component may be produced according to the method, which is coated with a layer.