A system (100), apparatus (110), and method (900) for creating a particle stream (70) that is deflected with a secondary gas (518) such as air before coming into contact with the treated substrate surface (80). The system (100) can be implemented as an improvement to a prior art PTWA (plasma transferred wire arc) thermal spraying apparatus (50) by using a non-symmetrical passageway configuration (549). Such a configuration can be an attribute of a nozzle (220) or a secondary gas director (576) such as an air baffle (578).

A thermal spraying torch configured to spray a molten material onto a thermal sprayed surface of a work object and form a thermal sprayed coating has a discharge port configured to discharge the molten material, a discharge port periphery located on a peripheral edge of the discharge port on a front side in a discharge direction of the molten material and extending in the discharge direction, and an external surface continuous with a front end of the discharge port periphery. The discharge port periphery includes first section to which the molten material adheres more easily than to the external surface. The external surface includes a second section to which the molten material adheres less easily than to the discharge port periphery.

A thermal spraying device includes an electric arc spraying device, a rotatable worktable, spraying tools, wire placing racks and a master controller. The electric arc spraying device is arranged at a periphery of a rotatable worktable, the spraying tools are arranged on the rotatable worktable in a circumference direction, and each of the spraying tools is driven to rotate by a motor. The wire placing racks are arranged at an outside of the rotatable worktable, and each of the wire placing racks corresponds to one electric arc spraying device. The master controller is connected to the rotatable worktable to control the rotatable worktable. Compared with a handheld electric arc spraying gun, the spraying efficiency and the stability of the spraying quality are improved. A thermal spraying device having the electric arc spraying device is further provided. A thermal spraying system and a thermal spraying technology are further provided

An atmospheric pressure pulsed arc plasma source and method of using including a housing having a housing opening therein; an insulator tube having an insulator tube opening therein, retained within the housing opening; and a conductive tube, retained within the insulator tube opening. A nozzle is retained by the housing. A feed path is defined in the conductive tube and the nozzle and a gas feed port is operatively coupled to the feed path. Feedstock is provided in the feed path and electrically coupled to the conductive tube. A pulsed DC power source provides a pulsed voltage to the conductive tube. The plasma source emits a discharge stream having a temperature that is less than 50 C. from the nozzle and a coating is formed on a substrate.

A thermal spraying torch configured to spray a molten material onto a thermal sprayed surface of a work object and form a thermal sprayed coating has a discharge port configured to discharge the molten material, a discharge port periphery located on a peripheral edge of the discharge port on a front side in a discharge direction of the molten material and extending in the discharge direction, and an external surface continuous with a front end of the discharge port periphery. The discharge port periphery includes first section to which the molten material adheres more easily than to the external surface. The external surface includes a second section to which the molten material adheres less easily than to the discharge port periphery.

A plasma transfer wire arc thermal spray system includes a section for feeding a wire acting as a first electrode, a source of plasma gas providing plasma gas, a nozzle directing the plasma gas stream from the source of plasma gas to a free end of the wire, and a second electrode located in the plasma gas stream towards the nozzle. In certain instances, the nozzle is made at least partially of electrically insulating material. The thermal spray apparatus with the inventive spray gun may have a simplified and faster starting procedure and the spray nozzle can be more durable.

Device for spray coating embraces a wire arc spray head that includes arc-making contact points and a carrier gas outlet, which is configured to swivel with feed wire in a pivoting motion. The device can be operated to spray coat a work piece.

The invention relates to a device for thermally coating a surface, which has at least one housing (6), a cathode (9), a primary gas distributor (11), a secondary gas distributor (12), electrically and thermally acting insulation elements (13, 14, 16), and an anode, which is designed as a consumable wire and is guided into a nozzle (19, 21) by means of a wire guide (18), wherein the nozzle (19, 21) is mounted in a centered manner and has openings (23) arranged radially in one plane on one of its sides (22).

An additive manufacturing system includes an additive manufacturing tool configured to supply a plurality of droplets to a part, a temperature control device configured to control a temperature of the part, and a controller configured to control the composition, formation, and application of each droplet to the plurality of droplets to the part independent from control of the temperature of the part via the temperature control device. The plurality of droplets is configured to build up the part. Each droplet of the plurality of droplets includes at least one metallic anchoring material.

The invention relates to a device for thermally coating a surface, which has at least one housing, a cathode, which is designed as a consumable wire and at least one insulation element, wherein the housing has a non-detachable anti-adhesion layer.