A multistage centrifugal atomizer comprises an outer shell that contains an inlet port and an outlet port and that encloses a tundish, a first inclined rotating surface and a second inclined rotating surface. The first inclined rotating surface is opposedly disposed to the second inclined rotating surface. The inlet is used to introduce a molten material into the multistage atomizer and the outlet is used to remove ultrafine particles having a D50 of less than 20 micrometers.

A multi-stage gas atomization preparation method of titanium alloy spherical powder for a 3D printing technology includes the following steps: bar preparation and machining step, multi-stage gas atomization powder preparation step through vacuum induction, and powder screening step. The collision probability of the metal droplets at the gas atomization stage is reduced by controlling the gas atomization pressure and the feeding speed of the titanium alloy electrode bar in a hierarchical manner, so that the collaborative control of the particle size and the surface quality of the titanium alloy 3D printing powder in the gas atomization preparation process is realized.

A load lock system for manufacturing a metal alloy using a feed material includes a process chamber having a controlled atmosphere, a feed chamber in flow communication with the process chamber having controlled atmosphere capabilities configured to contain a quantity of the feed material, and a collection chamber in flow communication with the process chamber having controlled atmosphere capabilities configured to collect the metal alloy manufactured in the process chamber. The system also includes a gate valve between the process chamber and the feed chamber configured to either allow passage of the feed material between the chambers, or to seal the process chamber from the feed chamber. The system also includes a discharge valve between the process chamber and the collection chamber configured to either allow passage of the metal alloy between the chambers, or to seal the process chamber from the collection chamber.

The present invention is directed to a method to produce silver nanoparticles. The method includes the steps of dropwise addition of silver nitrate solution to a carboxymethyl cellulose solution (1%) while stirring. The solution is subjected to ultrasonic irradiation for 30 minutes. The first indication of silver nanoparticles being synthesized can be change in the color of the solution to yellowish-brown after Ultrasonication. The solution can thereafter be subjected to microwave irradiations. After the predetermined duration, the produced silver nanoparticles can be separated from the solution. The nanoparticles can be washed and freeze dried.

A print engine of an additive manufacturing system includes a print station configured to hold a removable cartridge containing powder. A laser engine is positioned to direct a one or two dimensional patterned laser beam into the removable cartridge. In some embodiments powder is produced at least in part with a magnetohydrodynamic system.

A print engine of an additive manufacturing system includes a print station configured to hold a removable cartridge containing powder. A laser engine is positioned to direct a one or two dimensional patterned laser beam into the removable cartridge. In some embodiments powder is produced at least in part with a magnetohydrodynamic system.

Provision module (2) for providing additive manufacturing powder, comprising a main hopper (29) for storing additive manufacturing powder, the main hopper (29) being designed to be connected to a manufacturing module (4) configured to additively manufacture an object from the powder located in the main hopper (29), an inlet (211) of the provision module (2), which inlet is designed to be connected to the manufacturing module (4) and to receive powder located in the manufacturing module (4), a glovebox (25) designed to receive a container (28), the glovebox (25) being able to be closed in a sealed manner, a supply circuit configured to transfer powder located in the glovebox (25) to the main hopper (29), an extraction circuit that is different from the supply circuit and is configured to transfer additive manufacturing powder from the inlet (211) of the provision module (2) to the container (28), when the container (28) is received in the glovebox (25), the glovebox (25) comprising gloves (251) for closing the container (28) once it has been filled with powder, while the glovebox (25) is closed.

Provision module (2) for providing additive manufacturing powder, comprising a main hopper (29) for storing additive manufacturing powder, the main hopper (29) being designed to be connected to a manufacturing module (4) configured to additively manufacture an object from the powder located in the main hopper (29), an inlet (211) of the provision module (2), which inlet is designed to be connected to the manufacturing module (4) and to receive powder located in the manufacturing module (4), a glovebox (25) designed to receive a container (28), the glovebox (25) being able to be closed in a sealed manner, a supply circuit configured to transfer powder located in the glovebox (25) to the main hopper (29), an extraction circuit that is different from the supply circuit and is configured to transfer additive manufacturing powder from the inlet (211) of the provision module (2) to the container (28), when the container (28) is received in the glovebox (25), the glovebox (25) comprising gloves (251) for closing the container (28) once it has been filled with powder, while the glovebox (25) is closed.

A deployable manufacturing center (DMC) system includes a foundry module containing a metallurgical system configured to convert a raw material into an alloy powder, and an additive manufacturing (AM) module containing an additive manufacturing system configured to form the alloy powder into metal parts. The deployable manufacturing center (DMC) system can also include a machining module containing a machining system configured to machine the metal parts into machined metal parts, and a quality conformance (QC) module containing an inspection and evaluation system configured to inspect and evaluate the metal parts. A process for manufacturing metal parts includes the steps of providing the deployable manufacturing center (DMC) system; deploying the (DMC) system to a desired location; forming an alloy powder from a raw material using the deployable foundry module; and then forming the metal parts from the alloy powder using the additive manufacturing (AM) module.

A method of making dispersion-strengthened alloy particles involves melting an alloy having a corrosion and/or oxidation resistance-imparting alloying element, a dispersoid-forming element, and a matrix metal wherein the dispersoid-forming element exhibits a greater tendency to react with a reactive species acquired from an atomizing gas than does the alloying element. The melted alloy is atomized with the atomizing gas including the reactive species to form atomized particles so that the reactive species is (a) dissolved in solid solution to a depth below the surface of atomized particles and/or (b) reacted with the dispersoid-forming element to form dispersoids in the atomized particles to a depth below the surface of said atomized particles. The atomized alloy particles are solidified as solidified alloy particles or as a solidified deposit of alloy particles. Bodies made from the dispersion strengthened alloy particles, deposit thereof, exhibit enhanced fatigue and creep resistance and reduced wear as well as enhanced corrosion and/or oxidation resistance at high temperatures by virtue of the presence of the corrosion and/or oxidation resistance imparting alloying element in solid solution in the particle alloy matrix.