A rotary electric machine member manufacturing method includes: a step of providing a motor core by stacking a plurality of electromagnetic steel sheets; and a step of welding the motor core by keyhole welding while pressurizing the motor core in a stacking direction with a welding pressure lower than that at which the thickness of the motor core in the stacking direction levels off. The thickness is a length of the motor core between a first end of the motor core and a second end of the motor core.

A method for processing a powder material includes feeding a powder material through an additive processing machine to deposit multiple layers of the powder material onto one another and using an energy beam to thermally fuse selected portions of the layers to one another with reference to data relating to a particular cross-section of an article being formed. The powder material has spherical metal particles and a spaced-apart distribution of ceramic nanoparticles attached to the surfaces of the particles. The ceramic nanoparticles form a dispersion of reinforcement through the formed article.

A solder alloy for joining a Cu pipe and/or a Fe pipe has an alloy composition comprising in mass %: Sb: 5.0% to 15.0%; Cu: 0.5% to 8.0%; Ni: 0.025% to 0.7%; and Co: 0.025% to 0.3%, with a balance being Sn. The alloy composition satisfies the relationship of 0.07Co/Ni6, where Co and Ni represent contents of Co and Ni in mass %, respectively.

A hybrid mold includes (a) an Invar eggcrate structure, (b) an Invar interim working surface and (c) a CF composite material overlay. The eggcrate and interim working surface are welded or otherwise connected together to form a unitary base mold. The CF overlay is bonded to the interim working surface. The CF overlay is easily reconfigurable and can be replaced without destroying the integrity of the base mold.

A method for forming graphene-oxide (GO) embedded with gallium-iron alloy (galfenol) nanoparticles. The method includes submerging galfenol bulk material in a solution comprising deionized water and polyvinylpyrrolidone (PVP). The method includes ablating, a first time, the galfenol bulk material submerged in the solution with a laser. The method includes removing the galfenol bulk material from the solution after ablating with the laser. The method includes drying the galfenol bulk material after removing the galfenol bulk material from the solution. The method includes submerging galfenol bulk material in deionized water after drying the galfenol bulk material. The method includes ablating, a second time, the galfenol bulk material submerged in the deionized water and ablating a second time the galfenol bulk material submerged in the deionized water.

A low-temperature joining method effectively suppresses reductions in the mechanical properties of a junction of various types of high-tensile steel or aluminum, and of a heat-affected zone; and produces a joint structure. A method for joining two metal materials by forming a joint interface in which the two metal materials face each other at a joint portion and plunge a rotation tool caused to rotate at a prescribed speed into the joint, the method for low-temperature joining of metal materials characterized in that the peripheral velocity of the outermost periphery of the rotation tool is set to 51 mm/s or less, whereby the recrystallization temperature inherent to the metal materials is reduced by introducing a large strain to the joint, and recrystallized grains are generated at the joint interface by setting the joining temperature to less than the recrystallization temperature inherent to the metal materials.

Disclosed herein are embodiments of wear resistant alloys, such as ferrous alloys, that can have reduced carbide contents. In some embodiments, the alloys may have no carbides. In some, the alloy may have boride phases, such as phases having high Mo+W content and/or high Fe+Cr content. There can be reduced hardphases levels out of the specifically disclosed boride phases in some embodiments. In some embodiments, hypereutectic chromium borides can have limited incorporation into the disclosed alloys.

A method for forming a diffusion cooling hole in a substrate includes removing material from the substrate to form a metering section having an inlet on a first side of the substrate and removing material from the substrate to form a diffusing section that extends between the metering section and an outlet located on a second side of the substrate generally opposite the first side. The method also includes forming a feature on a substrate surface within one of the metering section and the diffusing section. Forming the feature includes depositing a material on the substrate surface and selectively heating the material to join the material with the substrate surface and form the feature.

Device (1) including a head (5) for induction pre-heating the adjacent edges of at least one item requiring welding which have to be joined, in which a sliding-block-shaped supporting structure (8) capable of moving above the edges to be welded (2, 3) and parallel thereto carries a first U-shaped inductor (9) in a first plane parallel to a plane containing the edges which have to be welded and carries a second inductor (14) which is U-shaped in a second plane perpendicular to the first plane in such a way that a first and second branch (16, 17) respectively of a tube (15) of the second inductor (14) are placed between the edges which have to be welded, at a predetermined distance (K) from the first inductor (9), when in use.

A tool for forming a shaped product has a support body that is fabricated from a first material, such as for instance cast iron. The first material defines a first portion of a forming surface of the tool and has a feature supported thereon. The feature has a layer of a second material that is supported on the first material of the support body, a layer of a third material that is supported on the layer of the second material and a layer of a fourth material that is supported on the layer of the third material. The layer of the fourth material, such as for instance a tool steel alloy, defines a second portion of the forming surface of the tool. During use the first portion of the forming surface and the second portion of the forming surface cooperate to form a desired shape of the shaped product.