An additive manufacturing method of manufacturing a product by laminating metal includes: laminating the metal so as to form a half-finished product of the product and a support; and spraying dry ice pellets having a particle shape to the support, after the laminating.

An additive manufacturing method of manufacturing a product by laminating metal includes: laminating the metal so as to form a half-finished product of the product and a support; and spraying dry ice pellets having a particle shape to the support, after the laminating.

A dynamic compaction process comprises forming first and second preforms. Forming each preform includes utilizing a container having an interior and an exterior. Filling the interior of the container with a powder material; sealing the container; subjecting the exterior of the container to an instantaneous dynamic compaction, forming a solid powder metallurgy preform encased by the container. The container gets removed from each preform. The process includes inserting the first and second preforms in another container in a predefined pattern; the predefined pattern aligns the first and second preforms creating an interface. The process includes inserting a backstop against the predefined pattern in this container; subjecting the exterior of this container to an instantaneous dynamic compaction. The process includes bonding the first preform and second preform along the interface to form a component precursor; and removing the container from the precursor. Another step includes processing the precursor into components.

A dynamic compaction process comprises forming first and second preforms. Forming each preform includes utilizing a container having an interior and an exterior. Filling the interior of the container with a powder material; sealing the container; subjecting the exterior of the container to an instantaneous dynamic compaction, forming a solid powder metallurgy preform encased by the container. The container gets removed from each preform. The process includes inserting the first and second preforms in another container in a predefined pattern; the predefined pattern aligns the first and second preforms creating an interface. The process includes inserting a backstop against the predefined pattern in this container; subjecting the exterior of this container to an instantaneous dynamic compaction. The process includes bonding the first preform and second preform along the interface to form a component precursor; and removing the container from the precursor. Another step includes processing the precursor into components.

A method of producing a reactive powder includes providing a bulk structure of reactive material comprising a first reactant and a second reactant, the bulk structure having a preselected average spacing between the first and the second reactants; and mechanically processing the bulk structure of reactive material to produce a plurality of particles from the bulk structure such that each of the plurality of particles comprises the first and second reactants having an average spacing that is substantially equal to the preselected average spacing of the bulk structure of reactive material. The first and second materials of the plurality of particles react with each other in an exothermic reaction upon being exposed to a threshold energy to initiate the exothermic reaction and remain substantially stable without reacting with each other prior to being exposed to the threshold energy.

A method of producing a reactive powder includes providing a bulk structure of reactive material comprising a first reactant and a second reactant, the bulk structure having a preselected average spacing between the first and the second reactants; and mechanically processing the bulk structure of reactive material to produce a plurality of particles from the bulk structure such that each of the plurality of particles comprises the first and second reactants having an average spacing that is substantially equal to the preselected average spacing of the bulk structure of reactive material. The first and second materials of the plurality of particles react with each other in an exothermic reaction upon being exposed to a threshold energy to initiate the exothermic reaction and remain substantially stable without reacting with each other prior to being exposed to the threshold energy.

A method for composite additive manufacturing with dual-laser beams for laser melting and laser shock, includes the following steps: 1) performing cladding on metal powder through a first continuous laser beam by thermal effect, and performing synchronous shock forging on material in a cladding region through a second short-pulse laser beam by shock wave mechanical effect, so as to perform the composite additive manufacturing; and 2) stacking the material in the cladding region layer by layer to form a workpiece. The method has the characteristics that the two laser beams make full use of the thermal effect and the shock wave mechanical effect, and synchronously work in a coupled manner, so that defects such as pores, incomplete fusion and shrinkage in a cladding layer are eliminated, and the performance of the workpiece is obviously improved. The method is high in manufacturing efficiency.

A method for composite additive manufacturing with dual-laser beams for laser melting and laser shock, includes the following steps: 1) performing cladding on metal powder through a first continuous laser beam by thermal effect, and performing synchronous shock forging on material in a cladding region through a second short-pulse laser beam by shock wave mechanical effect, so as to perform the composite additive manufacturing; and 2) stacking the material in the cladding region layer by layer to form a workpiece. The method has the characteristics that the two laser beams make full use of the thermal effect and the shock wave mechanical effect, and synchronously work in a coupled manner, so that defects such as pores, incomplete fusion and shrinkage in a cladding layer are eliminated, and the performance of the workpiece is obviously improved. The method is high in manufacturing efficiency.

The invention relates to a compacted and densified metal material comprising one or more phases formed of an agglomerate of grains, the cohesion of the material being provided by bridges formed between grains, said material having a relative density higher than or equal to 95% and preferably higher than or equal to 98%.

The invention relates to a compacted and densified metal material comprising one or more phases formed of an agglomerate of grains, the cohesion of the material being provided by bridges formed between grains, said material having a relative density higher than or equal to 95% and preferably higher than or equal to 98%.