A device may include an electrically-operated propellant or energetic gas-generating material, additively manufactured together with electrodes for producing a reaction in the material. The device may also include a casing that is additively manufactured with the other components. The additive manufacturing may be accomplished by extruding or otherwise depositing raw materials for the different components where desired. The electrodes may be made of a conductive polymer material, for example using an electrically-conductive fill in a polymer.

A device may include an electrically-operated propellant or energetic gas-generating material, additively manufactured together with electrodes for producing a reaction in the material. The device may also include a casing that is additively manufactured with the other components. The additive manufacturing may be accomplished by extruding or otherwise depositing raw materials for the different components where desired. The electrodes may be made of a conductive polymer material, for example using an electrically-conductive fill in a polymer.

The invention relates to a method for coating cavity walls, in particular cylinder bores of engine blocks. In the method, a coating is applied to a cavity wall using a coating lance. In addition, a cavity diameter is measured using a measuring apparatus. According to the invention, the method is characterized in that at least a plurality of diameter values of a first cavity are measured at different heights of the first cavity using the measuring apparatus, and in that a coating of variable thickness is applied to a wall of the first or a second cavity using the coaling lance, the thickness of said coating of variable thickness being dependent on the determined diameter values. The invention additionally describes a corresponding coating system.

A powder feeder according to one aspect of the present disclosure is a powder feeding device that feeds powder from a feeder to a nozzle. The powder feeding device includes a cartridge configured to store the powder in an airtight condition, and includes the feeder. The cartridge includes a port from which the powder is stored and withdrawn, and an open/close valve for opening and closing the port. The feeder includes a connection portion to which the cartridge is removably connected, a supply port configured to supply the powder in the cartridge connected to the connection portion into the feeder, and an opening/closing valve for opening and closing the supply port. The feeder is configured to insert the powder supplied from the supply port to the feeder into the nozzle, and the cartridge and the feeder are configured to form an enclosed space between the port and the supply port in response to the cartridge being connected to the connection portion.

A powder feeder according to one aspect of the present disclosure is a powder feeding device that feeds powder from a feeder to a nozzle. The powder feeding device includes a cartridge configured to store the powder in an airtight condition, and includes the feeder. The cartridge includes a port from which the powder is stored and withdrawn, and an open/close valve for opening and closing the port. The feeder includes a connection portion to which the cartridge is removably connected, a supply port configured to supply the powder in the cartridge connected to the connection portion into the feeder, and an opening/closing valve for opening and closing the supply port. The feeder is configured to insert the powder supplied from the supply port to the feeder into the nozzle, and the cartridge and the feeder are configured to form an enclosed space between the port and the supply port in response to the cartridge being connected to the connection portion.

A cooling system for a cold spray nozzle or a thermal spray barrel and a fabrication method thereof are provided. The cooling system includes a sleeve with cooling fins that encapsulate a spray nozzle or barrel to enable heat transfer from the nozzle or barrel to the fins and then to the external ambient environment. The sleeve may optionally include one or more channels with cooling tubes to enable enhanced cooling with a cooling medium flowing through the tubes and across the fins.

A method and coating system are provided that use a temperature controlled gas flow to smooth a surface of a ceramic, like a thermal barrier coating (TBC). Thermal spray coating unit coats a ceramic on a surface. The thermal spray coating unit creates a flow of ceramic material towards the surface. A layer of at least partially molten ceramic material on the surface is smoothed by transmitting a flow of temperature controlled gas across the at least partially molten ceramic material on the surface after the thermal spray coating of the ceramic on the surface. The solidified ceramic has a smoother surface that requires much less polishing to attain a desired surface roughness.

Proposed is a method of producing an yttrium-based thermal spray coating. The method includes forming a coating on a substrate by atmospheric plasma spraying of an yttrium-based granular powder including at least one yttrium compound powder selected from the group consisting of Y.sub.2O.sub.3, YOF, YF.sub.3, Y.sub.4Al.sub.2O.sub.9, Y.sub.3Al.sub.5O.sub.12, and YAlO.sub.3, and a silica (SiO.sub.2) powder. The yttrium-based granular powder includes less than 10 w % of a Y—Si—O mesophase. Then yttrium-based thermal spray coating can exhibit low porosity, high density, and excellent plasma resistance.

An apparatus for preparing graphene by means of laser irradiation in liquid, comprising a laser generating system, and further comprising a computer control system, a cleaning and drying system, and a workpiece auxiliary system. The light spot diameter of the laser emitted from a pulse laser unit (26) is increased by means of a beam expander (24), and the laser is reflected and split by a beam splitter to form two laser beams; a first laser beam (19) shocks the right vertical plane of a graphite solid target (18) by means of a focusing lens, and a second laser beam (17) shocks the left vertical plane of the graphite solid target (18) by means of the focusing lens, so as to grow graphene on a copper foil (5) substrate.

A method of mask-free printing of dry nanoparticles, the method comprising generating a dry nanoparticle stream from a feedstock material in an atmospheric gas flow using a laser ablation system at atmospheric pressure, the dry nanoparticle stream uncontaminated by a fluidic carrier medium, wherein the dry nanoparticles uncontaminated by a fluidic carrier medium are directed to a substrate through a nozzle by the gas flow in a dry state and adhere to the substrate.