A method and device for injection moulding, in particular for micro-injection moulding, at least comprising a mould with a first mould half and a second mould half, wherein the first mould half and the second mould half define an injection moulding space in the closed state of the mould, and an insert arranged in the injection moulding space.

A method for manufacturing a structured embossing cylinder for embossing system including the steps of providing a hard-coated embossing roller having a cylindrically-shaped core and a hard-coating layer on the cylindrically-shaped core, the hard-coating layer having a thickness in a range between 1 gm and 10 gm, and having a surface-roughness value RA of less than 100 nm, depositing a masking layer on the hard-coating layer, the masking layer having a thickness of equal or less than 100 nm, removing material from the masking layer to form at least one opening, and etching to remove material at the at least one opening of the masking layer from the hard-coating layer to form a surface cavity in the hard-coating layer at the at least one opening, the surface cavity forming a structural embossing feature into the hard-coating layer, thereby forming the structured embossing cylinder.

An injection molding apparatus includes a substantially circular first substrate, a substantially circular second substrate disposed to face a surface of the first substrate, a fixing member which fixes a peripheral end portion of the first substrate and a peripheral end portion of the second substrate, and an injection portion which is provided in the fixing member and from which a composition is injected into a gap between the first substrate and the second substrate, in which a space connecting with the injection portion and the gap is provided in at least a part of a periphery of the gap, and a width of the space in a thickness direction is larger than a width of the gap in the thickness direction.

Apparatus and methods are described including a progressive lens that is configured to provide a far-vision correction and a near-vision correction. The progressive lens includes a single-focus, far-vision corrective lens that is configured to provide only a portion of the far-vision correction, and a film coupled to the single-focus, far-vision corrective lens. The film defines a far-vision corrective portion that is configured to provide the remainder of the far-vision correction, a near-vision corrective portion that is configured to provide additive near-vision correction, and an intermediate portion in which the film transitions between the far-vision corrective portion and the near-vision corrective portion. Other applications are also described.

The present invention relates to a pressure relief element (11) to be used as an overpressure safety means in devices where a gaseous medium must be rapidly released in case of overpressure, wherein the pressure relief element (11) has at least one notch (9) which is designed as a predetermined breaking point where the pressure relief element (11) breaks at a certain level of overpressure, thereby irreversibly opening an exhaust path for the gaseous medium. The present invention also relates to a pressure relief device of an electrochemical battery, comprising such a pressure relief element and a battery comprising such a pressure relief device.

The inventive method for manufacturing a medical device having a shuttle mold system mounted in a vertical injection molding machine, the shuttle mold system having a top section and two bottom sections, with the two bottom sections mounted 180 degrees from each other on a rotating table and the top section mounted in a fixed position above the rotating table, and where after molding, the table rotates 180 degrees for removal of parts and inserting fixtures for the next device manufacture cycle.

A system is disclosed for micro-molding articles. The system melts and pre-pressurizes thermoplastic material to a first level, within a plasticizing barrel. The melt pressure of the thermoplastic material is manipulated to a second level, within a hot runner. The melt pressure of the thermoplastic material is manipulated to an ultra-cavity packing pressure within a valve gate nozzle.

A micro-structured mold-core of a microfluidic chip and its manufacturing method, which includes the steps of: installing a mold-core on a worktable of a five-axis machining center, and installing a micro-milling cutter and a fine milling-grinding tool on a tool holder of the five-axis machining center; rough-milling a surface of the mold-core using the micro-milling cutter according to a preset first machining track, to form a micro-projection array structure with a specific shape; finishing a surface of the micro-projection array structure formed by rough-milling using the fine milling-grinding tool according to a preset second machining track, to form a desired micro-projection array structure; and installing the mold-core on an injection molding machine, and adding particle material of polymer for micro injection molding to form a microfluidic chip, or installing the mold-core on a hot-embossing machine, and adding block material of polymer for hot embossing to form a microfluidic chip.

A hook-and-loop fastener connector having a plurality of hooks (7) arranged on a base plate (16). The hooks (7) exhibit a hook foot (8) and a hook head (9). The hook foot (8) and hook head (9) are arranged within one plane. The plane (10) and the base plate (16) are angled to each other at an angle (β) greater than 90°.

The invention relates to an apparatus for producing a hook-and-loop fastener connector (18) via an injection molding method, which comprises: an injection mold (11) having a plurality of first and second mold halves (1;2), wherein each first mold half (1) exhibits a plurality of first cavities (3) in a first surface (4) and each second mold half (2) exhibits a plurality of second cavities (5 ) in a second surface (6), and the first and second surfaces (4;6) face each other and contact such that the first and second cavity (3; 5) together form an entire cavity in hook form, wherein the hook form (7) exhibits a hook foot (8) and a hook head (9), and the hook foot (8) and hook head (9) are arranged within one plane, wherein the hook foot (8) is formed at least by the first cavity (3) and the hook head (9) is formed at least by the second cavity (5), wherein the injection mold (11) has a longitudinal axis (12) along which the second mold halves (2) are displaceable in relation to the first mold halves (1), characterized in that the plane (10) and the longitudinal axis (12) are angled to one another.