The present invention discloses an integrated method for manufacturing a high-temperature resistant thin-walled component by preforming by laying a metal foil strip. The integrated manufacturing method includes: designing a preform, preparing a support die, determining a thickness of a foil strip, determining a width of the foil strip, developing a laying process, laying an A foil strip and a B foil strip, obtaining an AB laminated preform, bulging the preform, performing a reactive synthesis and a densification process of a bulged component, and performing a subsequent treatment of the thin-walled component. The present invention obtains an integral thin-walled preform with a complex structure, a uniform wall thickness and a shape close to the final part by continuously laying a metal foil strip with an appropriate width. The present invention does not need to weld the thin-walled preform, and thus solves the problem of weak comprehensive performance of a weld zone in the conventional method of preparing, rolling and welding a laminated sheet into a cylinder. In addition, the present invention reduces a subsequent bulging deformation, avoiding local bulging, thinning and cracking, undercuts at the parting during die closing, and wrinkles due to uneven distribution of materials in each zone.

The present invention discloses an integrated method for manufacturing a high-temperature resistant thin-walled component by preforming by laying a metal foil strip. The integrated manufacturing method includes: designing a preform, preparing a support die, determining a thickness of a foil strip, determining a width of the foil strip, developing a laying process, laying an A foil strip and a B foil strip, obtaining an AB laminated preform, bulging the preform, performing a reactive synthesis and a densification process of a bulged component, and performing a subsequent treatment of the thin-walled component. The present invention obtains an integral thin-walled preform with a complex structure, a uniform wall thickness and a shape close to the final part by continuously laying a metal foil strip with an appropriate width. The present invention does not need to weld the thin-walled preform, and thus solves the problem of weak comprehensive performance of a weld zone in the conventional method of preparing, rolling and welding a laminated sheet into a cylinder. In addition, the present invention reduces a subsequent bulging deformation, avoiding local bulging, thinning and cracking, undercuts at the parting during die closing, and wrinkles due to uneven distribution of materials in each zone.

An example embodiment of a method is disclosed for making a component including a high entropy alloy (HEA). The method includes combining a reaction component with a powdered HEA precursor to form a solid HEA feedstock. The solid HEA feedstock is converted into a powder suitable for use as a powder feedstock in an additive manufacturing device and capable of sustaining a self-propagating high-temperature synthesis (SHS) reaction. At least a portion of the powder feedstock is additively manufactured into a preformed shape approximating a desired shape of the component. The preformed shape is filled with the HEA powder feedstock. The powdered HEA precursor in the preformed shape are ignited to induce the self-propagating high-temperature synthesis (SHS) reaction, thereby forming a stable HEA component approximating the desired shape.

An example embodiment of a method is disclosed for making a component including a high entropy alloy (HEA). The method includes combining a reaction component with a powdered HEA precursor to form a solid HEA feedstock. The solid HEA feedstock is converted into a powder suitable for use as a powder feedstock in an additive manufacturing device and capable of sustaining a self-propagating high-temperature synthesis (SHS) reaction. At least a portion of the powder feedstock is additively manufactured into a preformed shape approximating a desired shape of the component. The preformed shape is filled with the HEA powder feedstock. The powdered HEA precursor in the preformed shape are ignited to induce the self-propagating high-temperature synthesis (SHS) reaction, thereby forming a stable HEA component approximating the desired shape.

An example embodiment of a method is disclosed for making a component including a high entropy alloy (HEA). The method includes combining a reaction component with a powdered HEA precursor to form a solid HEA feedstock. The solid HEA feedstock is converted into a powder suitable for use as a powder feedstock in an additive manufacturing device and capable of sustaining a self-propagating high-temperature synthesis (SHS) reaction. At least a portion of the powder feedstock is additively manufactured into a preformed shape approximating a desired shape of the component. The preformed shape is filled with the HEA powder feedstock. The powdered HEA precursor in the preformed shape are ignited to induce the self-propagating high-temperature synthesis (SHS) reaction, thereby forming a stable HEA component approximating the desired shape.

The disclosure relates to thermoelectric materials prepared by self-propagating high temperature synthesis (SHS) process combining with Plasma activated sintering and methods for preparing thereof. More specifically, the present disclosure relates to the new criterion for combustion synthesis and the method for preparing the thermoelectric materials which meet the new criterion.

The disclosure relates to thermoelectric materials prepared by self-propagating high temperature synthesis (SHS) process combining with Plasma activated sintering and methods for preparing thereof. More specifically, the present disclosure relates to the new criterion for combustion synthesis and the method for preparing the thermoelectric materials which meet the new criterion.

The disclosure provides a method for generating a solid metal object. Initially, a reductant material and a metal precursor particle mixture are arranged in a high temperature furnace that is filled with a chemically inert atmosphere. A temperature of the high temperature furnace is held above the decomposition temperature of the reductant but below a melting point of the metal precursor particle mixture for a predetermined duration to generate the solid metal object. At this stage, the generated metal object is cooled in the inert atmosphere.

The disclosure provides a method for generating a solid metal object. Initially, a reductant material and a metal precursor particle mixture are arranged in a high temperature furnace that is filled with a chemically inert atmosphere. A temperature of the high temperature furnace is held above the decomposition temperature of the reductant but below a melting point of the metal precursor particle mixture for a predetermined duration to generate the solid metal object. At this stage, the generated metal object is cooled in the inert atmosphere.

The disclosure relates to thermoelectric materials prepared by self-propagating high temperature synthesis (SHS) process combining with Plasma activated sintering and methods for preparing thereof. More specifically, the present disclosure relates to the new criterion for combustion synthesis and the method for preparing the thermoelectric materials which meet the new criterion.