A method for producing a metal shaped article having a porous structure includes a shaping step of shaping a shaped article including a plurality of columns that contain a resin material and that extend from a substrate, and a sintering target material by repeatedly performing a resin material supply step of supplying a liquid containing the resin material to a plurality of places of the substrate at intervals in two directions crossing each other, a curing step of curing the liquid, and a sintering target material supply step of supplying the sintering target material to the substrate, a removal step of removing the substrate, a degreasing step of degreasing the columns, and a sintering step of sintering the sintering target material.

A method for producing a metal shaped article having a porous structure includes a shaping step of shaping a shaped article including a plurality of columns that contain a resin material and that extend from a substrate, and a sintering target material by repeatedly performing a resin material supply step of supplying a liquid containing the resin material to a plurality of places of the substrate at intervals in two directions crossing each other, a curing step of curing the liquid, and a sintering target material supply step of supplying the sintering target material to the substrate, a removal step of removing the substrate, a degreasing step of degreasing the columns, and a sintering step of sintering the sintering target material.

A composite material comprising a metal matrix and nanocellulose supplement. The metal matrix is formed of a metal base material and may be monolithic throughout the composite material. The nanocellulose supplement improves a material property of the metal matrix and is formed of a nanocellulose supplement material dispersed in the metal base material. Importantly, the nanocellulose supplement material does not become damaged when the composite material is formed.

Bioresorbable porous biocomposites for orthopaedic applications. In an exemplary embodiment of a resorbable orthopaedic implant of the present disclosure, the implant comprises a porous alloy of at least a first metal and a second metal sintered together, the alloy configured to resorb into a body at substantially an atomic level without flaking off, wherein a porosity of the implant is defined by a first plurality of interconnected holes having a first range of sizes.

Disclosed is a wax-based thermoplastic organic binder composition consisting of: 50 to 94 wt % of a wax mixture comprising paraffin wax and microcrystalline wax; 3 to 35 wt % of a polyolefin copolymer having a carbonyl group as a backbone polymer; and 3 to 15 wt % of a process control agent.

Described are porous sintered bodies and methods of making porous sintered bodies by steps that include an injection molding step.

The present invention is a method for producing a porous metal body or a method for producing an electrode catalyst, which is capable of simplifying the production process and improving the production efficiency by not requiring a step of immersion in an acid treatment solution. A method for producing a porous metal body according to the present invention comprises: a step for forming a metal resin-containing layer, which contains a metal and a resin that has a lower melting point than the metal, on a base; and a step for obtaining a porous metal body by subjecting the metal resin-containing layer to a heat treatment, thereby sintering the metal and removing the resin from the metal resin-containing layer.

A porous material and preparation method thereof is provided. The material includes a material body. The body consists of pore cavities classified according to pore size of material and cavity walls surrounding to form the pore cavities. The lower-level pore cavities are arranged on the cavity walls of the upper-level pore cavities framed by surrounding a three-dimensional space. All the pore cavities are interconnected. The preparation method is: mixing raw powders with pore-forming agent for the smallest-level pore cavities of porous material to formulate slurry; uniformly filling the slurry into polymer material support to form green body and get dried and smashed to obtain mixed grains; uniformly mixing the mixed grains with pore-forming agent for upper-level pore cavities greater than the smallest-level pore cavities of porous material to make compact green body; performing vacuum sintering; performing the conventional follow-up treatment according to the raw materials process of porous material.

A heat transfer surface with a convective cooling layer includes a metal substrate and a porous metal foam layer transient liquid phase (TLP) bonded on the metal substrate. The porous metal foam layer includes a plurality of high melting temperature (HMT) particles and a plurality of micro-channels. A first TLP intermetallic layer is positioned between, and TLP bonds together, adjacent HMT particles to form the porous metal foam layer. A second TLP intermetallic layer is positioned between and TLP bonds a subset of the plurality of HMT particles to the metal substrate such that the porous metal foam layer is TLP bonded to the metal substrate. The plurality of micro-channels extend from an outer surface of the porous metal foam layer to the metal substrate such that a cooling fluid may be wicked through the plurality of micro-channels to the surface of the metal substrate.

A heat transfer surface with a convective cooling layer includes a metal substrate and a porous metal foam layer transient liquid phase (TLP) bonded on the metal substrate. The porous metal foam layer includes a plurality of high melting temperature (HMT) particles and a plurality of micro-channels. A first TLP intermetallic layer is positioned between, and TLP bonds together, adjacent HMT particles to form the porous metal foam layer. A second TLP intermetallic layer is positioned between and TLP bonds a subset of the plurality of HMT particles to the metal substrate such that the porous metal foam layer is TLP bonded to the metal substrate. The plurality of micro-channels extend from an outer surface of the porous metal foam layer to the metal substrate such that a cooling fluid may be wicked through the plurality of micro-channels to the surface of the metal substrate.