A single core pin assembly (10) having a first core pin (12) and at least one second core pin (14), the first core pin (12) having a first end (16), a second end (18) and a first core pin body (20). The first core pin body (20) connects the first end (16) and the second end (18). The second core pin (14) has a first end (24), a second end (26), and a second core pin body (28) connecting the second core pin first end (24) and the second core pin second end (26). The second core pin first end (24) is configured to join with the first core pin first end (16) to form a common downstream channel (30). The core pin (10) may be placed in a mold and surrounded by a flowable material (e.g. plastic) to form a work piece.

The invention relates to a method for producing an injection-molded part, the injection-molded part being a plastic cylinder for a needle-free syringe. The cylinder has an opening. The invention further relates to an injection-molding tool for producing the cylinder, the injection molded tool including an outer mold component and an inner mold component, which together define a clearance which determine the injection-molded part and the cylinder. The outer mold component and the inner mold component are designed such that the clearance is formed without an obstacle for plastic between the outer mold component and the inner mold component.

The invention relates to an injection mold for manufacturing an injection-molded component from plastic material. The injection mold including an outer first half-mold and an outer second half-mold, which, when joined, define an empty space, which determines an outer contour of the injection-molded component, and a core, which is located in the empty space and determines an inner contour of the injection-molded component. A wire passes through the core and the joined outer first half-mold and outer second half-mold, and plural pairs of clamping jaws fix the wire in its position. A method for manufacturing an injection-molded component is also disclosed.

An embodiment of a device is described. The device may include a body. The body includes an outer surface and an inner surface defining a bore within the body. The inner surface defines a maximum inner dimension of the bore no more than 10 millimeters. The bore has a longitudinal axis therethrough. The device may include a plurality of parting lines on the inner surface of the body. The device may include a recess in the inner surface of the body. The recess may be a housed recess and may have a depth in a lateral direction perpendicular to the longitudinal axis of the bore.

A sample cell (10) for a respired gas sensor has a single-piece injection molded main body (40) defining a gas flow path including an optical sampling bore (42), a gas inlet lumen (50) connected with the inlet end (44) of the optical sampling bore, and a gas outlet lumen (52) connected with the outlet end (46) of the optical sampling bore. The gas flow path includes at least two curved walls (100, 102, 104, 106). The sample cell may be manufactured by assembling mold pins (120, 122, 124, 126, 128) for defining the gas flow path wherein at least two mold pins (122, 124) have curved surfaces for defining the at least two curved walls of the gas flow path, and injection molding the single piece injection molded main body including removing the mold pins after defining the gas flow path including the at least two curved walls.

A protection tube with latch in which a latch that is formed engageable with an attachment hole of a panel is molded integral with a protection tube that receives an electric wire, and a manufacturing apparatus of the protection tube with latch. The protection tube with latch includes a latch to be engaged with the attachment hole of the panel having the electric wire wired therein disposed on an outer peripheral face of the protection tube that is formed tubular and receives the electric wire.

A one-step injection molding mold of a tubular product. The mold divides a product into two parts for one-step injection molding, and includes a mounting retainer plate, runner stripper plate, front and rear mold plates, ejector retainer plate, ejector baseplate and a mounting baseplate, which are stacked, wherein the ejector retainer plate and baseplate are fixed together, two side edges thereof having square blocks, a first and a second hydraulic cylinder are arranged at the top of the mold, a third hydraulic cylinder is arranged on the external side surface of the mounting baseplate, and a fourth hydraulic cylinder is arranged on one side surface of the front mold plate adjacent to the rear mold plate. Further, a one-step injection molding method of a tubular product, including steps 1-6. The mold and the molding method thereof may increase the product yield and ensure a safe production process.

A fuel tank including a built-in component is provided. The built-in component includes: a carrier part being a rigid body including a plurality of engaging parts, and a plurality of struts each including an engageable part to be engaged with one of the engaging parts. The engageable part of the strut includes an upper contact surface and a lower contact surface, which are formed spaced apart from each other in a height direction. The engaging parts of the carrier part each includes a biasing part that, when the strut is engaged with the engaging part, enters a space between the upper contact surface and the lower contact surface and generates biasing forces in directions to move the upper contact surface and the lower contact surface away from each other.

The invention relates to a method for producing a tubular component as an article from a thermoplastic synthetic material while using an injection-molding device having a tool that forms an article cavity, having means for filling the article cavity with a thermoplastic molding compound, and having an injection device for injecting a fluid into the article cavity, wherein the injection device comprises a nozzle body, wherein the method provides that the nozzle body is used as a mold core for molding the shape of an end of the article, that the nozzle body is used as a carrier for an additional component to be incorporated into the article, wherein: a) the nozzle body first equipped with the additional component, b) the nozzle body is introduced into the closed article cavity, or the tool is closed around the nozzle body, c) the article cavity in a further method step is at least partially filled with the thermoplastic molding compound, d) a pressurized fluid is then induced into the article cavity by means of the injection device, wherein part of the molding compound is displaced into a secondary cavity, and e) the article is de-molded. The invention furthermore relates to an injection-molding device for carrying out the method.

A support tube for a filter element, in which the support tube is an elongated tubular member having a central longitudinal axis extending through a hollow interior of the support tube. The support tube has a plurality of through openings extending through a circumferential wall of the support tube and is formed in one piece and a unitary component. The plurality of through openings are bounded by at least five longitudinal webs which are polygonal in cross section in at least some sections in the longitudinal direction of the support tube. The at least five longitudinal webs are in each case formed symmetrically.