A slider for slide fastener includes: a body including a pull tab attachment post; and a pull tab. The pull tab includes: a coupling member including an exposed portion and an embedded portion; and a pinching member including a first pinching portion including an annular end portion having an opening through which the embedded portion is to be inserted, and a second pinching portion provided to the first pinching portion with the embedded portion interposed therebetween. At least one of a front end surface and a rear end surface of the pull tab attachment post has a protrusion. And when the pull tab is tilted toward at least one of a front side and a rear side of the body, the protrusion locks the pull tab to restrict rotation of the pull tab.

A process and assembly for incorporating a molded automotive fluid dispensing and manifold distribution system into an injection molded panel, including the steps of providing a mold and forming in a first injection molded shot a thermoplastic panel of a first material, opening the mold and positioning against a surface of the panel a previously produced manifold distribution system including at least a main manifold section and at least one branching section communicating with a nozzle outlet and reclosing the mold and subsequently forming in a second injection molded shot a second softer thermoplastic material in order to bond the manifold system to the first show panel. Other steps include forming the manifold distribution system in a secondary cavity with the first shot panel, following which a pick-and-place robot aligns the panel and manifold prior to the shot of softer material.

A hitch step assembly comprises a first shot component injection molded from a first polymer compound with a high flexural modulus and a second shot component injection molded from a second polymer compound having a lower flexural modulus relative to the first shot compound. A post and a step body core are molded from the first polymer compound. A shell of the step body is molded from the second polymer compound and is overmolded onto the step body core. The shell forms a compression zone that attenuates rear impact forces the hitch step encounters, thus offering some protection against rear impacts. The hitch step assembly exhibits satisfactory resistance to deflection and torsional bending about a hitch receiver axis when a force is applied on the top surface of the hitch step near its lateral ends.

A decorative functional component with a transparent partial surface includes a substrate and a flat cover body. The substrate is of a first plastic material and has a recess. The cover body is of a transparent second plastic material and covers the recess of the substrate. The substrate and the cover body are connected together by a loose form-fit connection. The substrate and the cover body and are jointly coated with a low viscosity curing transparent plastic flooded thereon.

An in-mold electronic structure according to the present invention comprises a film with a design; a first plastic resin disposed under the film, and a second plastic resin disposed under the first plastic resin, wherein an electronic circuit is formed on a top side or both sides of the second plastic resin, wherein an electronic device is mounted on the top side or the both sides of the second plastic resin, wherein the film, the first plastic resin, and the second resin with the electronic circuit and the electronic device, are integrated.

An insert molding component includes a primary molding section having a concave portion formed in one surface thereof, the concave portion including stepped lower and upper concave portions, an insert component disposed on a bottom surface of the lower concave portion, a heat-insulating component disposed in the upper concave portion above an opening of the lower concave portion in which the insert component is disposed, and a secondary molding section disposed in contact with the one surface of the primary molding section.

A method for producing a stator for an electrical machine includes providing the stator including a ring-shaped stator body, from which a plurality of stator teeth arranged spaced apart along a circumferential direction of the stator body protrude radially to the inside. A space is thereby provided between two stator teeth adjacent to one another in the circumferential direction. Second, a first injection molding of two stator teeth adjacent to one another in the circumferential direction with a plastic is performed. Third, a stator winding is arranged in the space. Fourth, a second injection molding of the stator winding arranged in the space with the plastic is performed such that an air gap and/or an air trap between the stator teeth injection molded in the second step and the stator winding after the arrangement of the stator winding in the space in the third step, is filled with the plastic.

A sensor assembly comprising a first rotary sensor part having a plurality of individual electrically conducting code segments arranged in a circumferential pattern, and a plurality of electrically conducting reference segments between the code segments, and a second rotary sensor part arranged rotationally relative to the first part a plurality of contact structures, each contact structure being arranged to be in contact with either a code segment or a reference segment depending on the rotational position between the first and second rotary sensor part. The contact structures are configured to engage and connect to different sensor segments as the first and second rotary sensor part rotate relative to each, the created connections being indicative of a rotational position between the first and second rotary sensor part. For a given rotational position, at least one contact structure engages a code segment and at least one contact structure engages a reference segment.

A method for producing a component, and an injection-molding device. In the method. the following steps are carried out, in particular in succession: closing an injection mold, injection molding a base body by introducing a first plastic material into a first injection-molding cavity, opening the injection mold, stamping one or more first film elements and removing the component from the mold.

A molded circuit board (10) of a camera module (100), manufacturing equipment (200) and a manufacturing method for the molded circuit board. The manufacturing equipment (200) comprises a forming mold (210), which comprises a first mold (211) and a second mold (212) that can be opened or closed, where the first mold (211) and the second mold (212) form a forming cavity (213) when closed. Also, a light window forming block (214) and a base forming guide groove (215) located at the periphery of the light window forming block (214) are provided within the forming cavity (213). When a circuit board is mounted in the forming cavity (213), once a molding material (13) filled into the base forming guide groove (215) is solidified into form by undergoing a transition process from a liquid state to a solid state, a molded base (12) is formed at the position corresponding to the base forming guide groove (215), a through hole of the molded base (12) is formed at the position corresponding to the light window forming block (214), where the molded base (12) is integrally formed on the circuit board so as to form the molded circuit board (10) of the camera module (100). The through hole is used for providing the camera module (100) with an optical path. The molded base (12) can serve as a frame for the camera module (100).