A system and method for manufacturing a part in a mold having a mold cavity including a printhead for depositing a first material within the mold cavity, and an injection head for depositing a second material within the mold cavity. A part can be made in the mold cavity by the cooperative use of both injection molding and additive manufacturing steps.

A tool for overmoulding and/or backmoulding a curved glass body is proposed, the tool having a first surface for supporting the curved glass body. The tool comprises a plurality of pins, the pins each having a first end face at a first end of the pins, and at least one section of the first surface being formed by the first end faces of the pins. The pins are mounted to be displaceable in their longitudinal direction so that at least the section of the first surface can be adapted to a contour of the curved glass body.

A casing component according to an embodiment of the present technology includes a to-be-decorated area and a decoration portion. The to-be-decorated area includes a plurality of to-be-decorated surfaces to be decorated, the plurality of to-be-decorated surfaces being formed such that adjacent to-be-decorated surfaces have different heights. The decoration portion includes a metal layer formed in each of the plurality of to-be-decorated surfaces.

A molding method integrally molds thermoplastic resin and a flexible substrate mounted with a circuit and an electronic component on a flat plate having flexibility into a three-dimensional shape. The molding method includes the steps of determining an unfolded shape and circuit arrangement of the flexible substrate corresponding to the three-dimensional shape, elastically deforming and holding the flexible substrate along a resin filling space of a mold while the mold is being opened, and closing the mold and filling the resin filling space with thermoplastic resin.

A method for forming a hybrid heat exchanger is provided. The method includes laser-texturing a metal surface to create a plurality of microstructures and subsequently melt-bonding a plastic component to the plurality of microstructures. During melt-bonding, plastic material penetrates the plurality of microstructures and conforms to the plastic component to the metal surface. After hardening inside the microstructures, the plastic component adheres to the metal surface as a hybrid component. As a result, a fastener or snap connection is not required, and the plastic-metal joint provides a barrier to water, glycol-based fluids, air, and other fluids.

A mobile terminal case and a method of manufacturing the same are provided. The mobile terminal case includes a three-dimensional curved body or plane shape having a circumferential edge lower than its center and formed from a fiber reinforced composite material; and a gradation paint layer formed at an outer surface of the body formed from fiber reinforced composite material.

Disclosed herein is an injection molding method for making optical thermoplastic lenses using 3D—printed functional wafers. The method employs a variable injection molding cavity temperature that is heated to at least wafer Tg—10° C.

A mixing impeller has first and second subassemblies. A magnet is accommodated in the first subassembly and is adapted to be magnetically coupled to a drive device to be driven. The second subassembly has at least one impeller blade for mixing components when rotating the mixing impeller. The first and second subassemblies are formed as separate entities which are selectively engageable. A method of manufacturing the first subassembly and a method of assembling the mixing impeller also are provided.

A holding portion having a diameter larger than that of a cavity is formed in communication with the cavity, in an area of a two-part type mold, the area including a portion corresponding to an annular groove. Subsequently, an insert member formed in a cylindrical shape and provided with, on an outer circumferential surface, the annular groove having no step in a groove surface is fitted to the holding portion, and then the mold is closed. On an inner circumferential surface of the insert member, a surface treatment layer having a surface roughness rougher than those of other portions of the insert member is formed. Molten resin is injected into the cavity; thereafter, an assist material is injected into the cavity to mold the resin into a desired pipe body. Then, the insert member and the pipe body are integrated along with curing of the resin.

The invention relates to a device and a method for producing plastic moldings from at least two different sub-elements (15; 16) that includes first and second mold halves (3) and a rotatable center block (6) with center and third mold halves (8; 17) interposed therebetween. The center and third mold halves define first and second parting planes with the first and second mold halves. First cavities are defined in the first parting plane, into which a first plastic component is introduced to produce preforms (12). When the first parting plane is opened, the performs (12) remain on the center mold halves (8) and are brought into the second parting plane when the center block (6) is rotated, in which second parting plane second cavities are at least partially defined by the preforms (12), into which a second plastic component is introduced and first sub-elements (15) are produced. Second sub-elements (16) are produced in the additional cavities. When the second parting plane is opened, the sub-elements (15; 16) remain on the center and third mold halves (8) and are rotated into a lateral assembly position when the center block (6) is rotated.