A three-dimensional shaping apparatus includes a control unit configured to control a supply unit, a leveling unit, and an ejection unit to repeat a set of processes of supplying powder, forming powder layer, and ejecting shaping liquid to shape a three-dimensional shaped object corresponding to the shaping target. The control unit is configured to stop the set of processes in response to reception of a stop signal, and in response to reception of a resume signal after the reception of the stop signal, control the supply unit, the leveling unit, and the ejection unit to eject the shaping liquid onto at least a part of a dot region on a surface of an outermost powder layer, the dot region being formed by at least one dot formed at the outermost powder layer, and then resume the set of processes.

Disclosed herein is a method for manufacturing a rotor, the method including an injection process of injecting a bonded magnet material into a cavity of a molding die generating a magnetic field in the cavity so that the bonded magnet material is poured into each of the magnet slots in the rotor core set in the cavity through one of openings of each magnet slot, wherein the molding die used in the injection process has gates which respectively open at positions corresponding to regions, each of which ensures a view from the one of openings to the other opening of the magnet slot along an axial center of the rotor core.

A method includes injection molding a preform using a two phase injection system having a first phase in which a material is injected into the preform and a second phase in which the material is injected into the preform. The preform is disposed in a mold. The preform is blow molded into an intermediate article. The intermediate article is trimmed to form a finished container. The first phase includes injecting a material into the preform to form a single layer of the preform and the second phase includes injecting the material to form inner and outer layers and an intermediate layer between the inner and outer layers. The inner and outer layers include the material and the intermediate layer includes at least one additive. Finished containers are disclosed.

A method includes injection molding a preform using a two phase injection system having a first phase in which a material is injected into the preform and a second phase in which the material is injected into the preform. The preform is disposed in a mold. The preform is blow molded into an intermediate article. The intermediate article is trimmed to form a finished container. The first phase includes injecting a material into the preform to form a single layer of the preform and the second phase includes injecting the material to form inner and outer layers and an intermediate layer between the inner and outer layers. The inner and outer layers include the material and the intermediate layer includes at least one additive. Finished containers are disclosed.

The invention relates to a process for producing a beam guiding grid (4), comprising a molding having a grid of passageways (40) and wall areas surrounding them, from radiation-absorbing metal powder and binder, especially tungsten powder and binder. Advantageous production is achieved in that the molding is produced by injection molding, wherein the homogenized mixture, as a prepared flowable injection compound, is injected using an injection molding machine into a molding tool (7) that produces the molding, into which movable mold cores (72) were introduced prior to filing with the molding composition.

A method of forming multilayer polymer composite particles includes coextruding a multilayer polymer composite sheet having alternating first and second polymer layers. The multilayer polymer composite sheet is divided into a plurality of anisotropic multilayer polymer composite microparticles.

A three-dimensional shaping apparatus includes a control unit configured to control a supply unit, a leveling unit, and an ejection unit to repeat a set of processes of supplying powder, forming powder layer, and ejecting shaping liquid to shape a three-dimensional shaped object corresponding to the shaping target. The control unit is configured to stop the set of processes in response to reception of a stop signal, and in response to reception of a resume signal after the reception of the stop signal, control the supply unit, the leveling unit, and the ejection unit to eject the shaping liquid onto at least a part of a dot region on a surface of an outermost powder layer, the dot region being formed by at least one dot formed at the outermost powder layer, and then resume the set of processes.

A method includes injection molding a preform using a two phase injection system having a first phase in which a material is injected into the preform and a second phase in which the material is injected into the preform. The preform is disposed in a mold. The preform is blow molded into an intermediate article. The intermediate article is trimmed to form a finished container. The first phase includes injecting a material into the preform to form a single layer of the preform and the second phase includes injecting the material to form inner and outer layers and an intermediate layer between the inner and outer layers. The inner and outer layers include the material and the intermediate layer includes at least one additive. Finished containers are disclosed.

Three-dimensional (3D) printing systems include a 3D printer that includes a print bed that has one or more walls arranged to enclose a basin configured to contain a printing material. A compression plate is configured to fit slidably within, or on top surfaces of, the one or more walls of the print bed. A bottom plate forms a base of the basin and is configured to fit slidably within the one or more walls of the print bed. An elevation controller moves one or both of the compression plate and the bottom plate towards each other to apply a specified compressive force on printing material within the basin. The compression plate and the bottom plate together seal the basin sufficiently to avoid leakage of the print material from the basin.

A method and an arrangement for producing a workpiece using additive manufacturing techniques involve pre-process, in-process and post-process measurement in order to determine individual characteristics of one or more workpiece layers. In particular, dimensional and/or geometrical characteristics of a workpiece layer are measured before the next workpiece layer is produced. Advantageously, production parameters are controlled in response to individual material characteristics determined prior to the production process. Also advantageously, measurement results are fed back into a production process in order to increase accuracy, reliability, repeatability and precision of the production process.