A preparation method of cemented carbide with FeCoCu medium-entropy alloy as binding phase is provided. The preparation method includes: 1) preparing FeCoCu precursor powders by solution combustion synthesis; 2) preparing FeCoCu medium-entropy alloy powders by mechanical alloying; 3) evenly mixing the FeCoCu medium-entropy alloy powders with ultra-fine WC powders and a binder to obtain mixed powders and pressing the mixed powders into a shaped green body; 4) preparing a WC-FeCoCu cemented carbide by microwave sintering after removing the binder from the shaped green body. The preparation method reduces sintering temperature and time and obtains a new-type cemented carbide with fine grains, high hardness and good toughness while reducing the cost.

Reactor configurations may include one or more staged inlets and/or one or more staged outlets for gaseous and solid feedstocks. In one embodiment of the present disclosure, a reactor design for gas-solid reaction with one or more additional outlet for gas and/or solid phase is provided. In yet another embodiment, the design for a gas-solid reactor with one side inlet and two outlets for gas phase is described. In one embodiment, a reactor design with pairs of inlet and outlet for both gas and solid phase is provided. In another embodiment, a reactor design with one or more side inlets but only one outlet for gas phase is provided. In yet another embodiment, a reactor design with two inlets at the top/bottom of reactor and two side outlets for gaseous phase is described. In yet another embodiment, a reactor design with one or more side inlets and outlets for both gas and solid phases is provided.

A powder cleaning system can include a fluidized bed reactor configured to retain powder and fluidize the powder to remove adsorbate and/or other contaminants from the powder, and one or more gas sources configured to be in selective fluid communication with the fluidized bed reactor via at least one inlet line to selectively provide an inlet flow having one or more gases to the fluidized bed reactor to fluidize the powder with the one or more gases within the fluidized bed reactor. The system can include at least one outlet line in fluid communication with the fluidized bed reactor and configured to allow removal of outlet flow which comprises the adsorbate and/or other contaminants from the fluidized bed reactor.

Embodiments herein describe a method for hydrogen enhanced atomic transport. The method includes positioning a mold holding titanium metal particles of a titanium metallic powder in a chamber and, after flowing a gas mixture comprising hydrogen over the titanium metal particles in the chamber, positioning the chamber in a furnace that is preheated at a target temperature, where the target temperature is at least a decomposition temperature of titanium hydride. While maintaining the flow of the gas mixture, the titanium metal particles are heated to create a metallic product.

Embodiments herein describe a method for hydrogen enhanced atomic transport. The method includes positioning a mold holding titanium metal particles of a titanium metallic powder in a chamber and, after flowing a gas mixture comprising hydrogen over the titanium metal particles in the chamber, positioning the chamber in a furnace that is preheated at a target temperature, where the target temperature is at least a decomposition temperature of titanium hydride. While maintaining the flow of the gas mixture, the titanium metal particles are heated to create a metallic product.

The present invention concerns a method of making sintered components made from an iron-based powder composition and the sintered component per se. The method is especially suited for producing components which will be subjected to wear at elevated temperatures, consequently the components consists of a heat resistant stainless steel with hard phases including chromium carbo-nitrides. Examples of such components are parts in turbochargers for internal combustion engines.

In various embodiments, metallic alloy powders are utilized as feedstock, or to fabricate feedstock, utilized in additive manufacturing processes to form three-dimensional metallic parts. Such three-dimensional parts are fabricated by providing a powder bed containing particles each comprising a mixture and/or alloy of constituent elemental metals, forming a first layer of the part by (i) dispersing a binder into the powder bed, and (ii) curing the binder, the first layer of the shaped part comprising particles bound together by cured binder, disposing a layer of the particles over the first layer of the part, forming subsequent layers of the part, and then sintering the part.

In various embodiments, metallic alloy powders are utilized as feedstock, or to fabricate feedstock, utilized in additive manufacturing processes to form three-dimensional metallic parts. Such three-dimensional parts are fabricated by providing a powder bed containing particles each comprising a mixture and/or alloy of constituent elemental metals, forming a first layer of the part by (i) dispersing a binder into the powder bed, and (ii) curing the binder, the first layer of the shaped part comprising particles bound together by cured binder, disposing a layer of the particles over the first layer of the part, forming subsequent layers of the part, and then sintering the part.

A tooling assembly, including a cermet tool body and an electrically nonconductive polymer support body at least partially encapsulating the cermet tool body. The cermet tool body and electrically nonconductive polymer body further include a plurality of high magnetic permeability metallic particles distributed therethrough. Each respective high magnetic permeability metallic particle has a magnetic permeability of at least 0.0001 H/m. Each respective high magnetic permeability metallic particle has a relative permeability of at least 100.

A tooling assembly, including a cermet tool body and an electrically nonconductive polymer support body at least partially encapsulating the cermet tool body. The cermet tool body and electrically nonconductive polymer body further include a plurality of high magnetic permeability metallic particles distributed therethrough. Each respective high magnetic permeability metallic particle has a magnetic permeability of at least 0.0001 H/m. Each respective high magnetic permeability metallic particle has a relative permeability of at least 100.