An injection molding tool configured for being mounted in an injection molding apparatus for automated molding of work pieces in plastics, said injection molding tool comprising at least one main runner channel extending between the sprue channel and a runner branch where it branches into two or more branched runner channels leading to the mold cavities, and where at least the main runner channel downstream from the sprue channel comprises two flow channels being mutually joined at a runner junction downstream from the sprue channel, and wherein the two flow channels until the runner junction are linear and extending parallel to each other, and being completely or partly separated by a linear separating wall.

A rubber distributor for injection molds wherein the distributor comprises two or more modular units, sleeves each interchangeably insertable in a modular unit, one or more injectors to feed melted rubber to the distributor and one or more discharge nozzles to discharge the melted rubber from the distributor towards an external mold. Each sleeve has a through hole extending along the longitudinal axis of the same sleeve. Sleeves have a groove extending over respective side surfaces. Groove and the inner surface of the respective housing in the modular unit define a coil that can be supplied with a thermoregulating fluid whenever the sleeve is inserted into a modular unit. The modular units can be constrained to one another to define one or more channels for distribution of melted rubber that extend from an injector to one or more discharge nozzles, depending on a desired path. Modularity of the units allows the distributor to have ducts for distribution of melted rubber of a desired geometry. Through holes of the sleeves define corresponding lengths of at least one channel for distribution of melted rubber. Since the sleeves are cooled and the melted rubber flows inside them, the distributor is thermoregulated.

The invention relates to a cold runner block in a vertically operating injection molding machine for processing elastomer materials with an upper fixed molding platen and a molding platen arranged thereunder which is movable relative to the fixed molding platen, between which a molding tool having a plurality of mold cavities is arranged and wherein the cold runner block is arranged between the fixed molding platen and the molding tool, the cold runner block containing a distribution plate having the cold runners and containing a nozzle plate with nozzles each assigned to one of the plurality of mold cavities, which is characterized in that the distribution plate formed from a plurality of distribution strips (10-40) is arranged on a retaining plate (2), which can be fastened to the fixed, feed-side molding platen in such a way that each distribution strip (10-40) is connected by means of two bolts (3) to the retaining plate (2) in that the head (5) of each bolt (3) facing away from the distribution strip (10-40) forms a retaining element which is T-shaped in section, the retaining element being displaceably guided in the direction transverse to the distribution strip's longitudinal axis in guide rails (50) which are formed in the retaining plate (2) and are designed in section to complement the bolt head (5).

To provide a method for manufacturing an optical element, which improves the surface precision of the optical surface as well as reducing the birefringence at a low cost. A method for manufacturing an optical element 1090A having optical surfaces 1091 and 1092 and a non-optical surface 1093A that is adjacent to the optical surface 1092 via a ridge by injection molding includes forming the non-optical surface 1093A with a mold surface. The mold surface includes a sink forming area 1095 as a first area having a first surface roughness, and a high transfer area 1094 as a second area having a second surface roughness different from the first surface roughness. The second area is located outside the first area.

In various examples, a printbar is formed from multiple modular fluid ejection subassemblies joined together through a molding process that provides for a continuous planar substrate surface. A mold may secure the modular fluid ejection subassemblies during a molding process in which a runner conveys a molding material to seams between the joined modular fluid ejection subassemblies.

A resin shaping mold includes a hot runner, a cavity, a cold runner, and a valve pin. The cold runner is connected to the hot runner and the cavity. The cold runner has a lower temperature than the hot runner. The valve pin configured to move forward and backward from the hot runner toward the cold runner and close a channel of molten resin from the hot runner to the cavity at a predetermined position. The valve pin includes a runner lock portion configured to hold resin solidified at a position further on the cavity side with respect to the predetermined position in the cold runner.

A mold for an injection molding tool. The mold has a pin gate extending between a gate inlet and a gate opening. The pin gate forms a tapered, cylindrical channel through a body of the mold and abruptly transitions to a smooth funnel. The gate opening is positioned at an end of the funnel. The pin gate is configured to receive molding material from a runner channel of the injection molding tool at the gate inlet and dispense the molding material at the gate opening. The mold also has a mold cavity in fluid connection with the gate opening of the pin gate and configured to receive the molding material therefrom.

An injection molding machine with an injection system and a clamping system. The injection system may include a removable injection module defining a portion of the material flow path. The injection module may include all of parts that come in contact with the material between the material source and the mold. The injection module may include a valve arrangement movable between a fill position to load the injection module with material and an inject position to eject material from the injection module into the mold. The actuators for the injection module may be supported on the machine rather than the injection module. The clamping system may include a platen linear actuator to open and close the mold, and a hydraulic clamping system to apply clamping force to the closed mold. The hydraulic clamping system may include a free-float valve manifold assembly that selectively places the hydraulic cylinders in free-float mode.

The invention relates to a cold runner block in a vertically operating injection molding machine for processing elastomer materials with an upper fixed molding platen and a molding platen arranged thereunder which is movable relative to the fixed molding platen, between which a molding tool having a plurality of mold cavities is arranged and wherein the cold runner block is arranged between the fixed molding platen and the molding tool, the cold runner block containing a distribution plate having the cold runners and containing a nozzle plate with nozzles each assigned to one of the plurality of mold cavities, which is characterized in that the distribution plate formed from a plurality of distribution strips (10-40) is arranged on a retaining plate (2), which can be fastened to the fixed, feed-side molding platen in such a way that each distribution strip (10-40) is connected by means of two bolts (3) to the retaining plate (2) in that the head (5) of each bolt (3) facing away from the distribution strip (10-40) forms a retaining element which is T-shaped in section, the retaining element being displaceably guided in the direction transverse to the distribution strip's longitudinal axis in guide rails (50) which are formed in the retaining plate (2) and are designed in section to complement the bolt head (5).

A rubber distributor for injection molds wherein the distributor comprises two or more modular units, sleeves each interchangeably insertable in a modular unit, one or more injectors to feed melted rubber to the distributor and one or more discharge nozzles to discharge the melted rubber from the distributor towards an external mold. Each sleeve has a through hole extending along the longitudinal axis of the same sleeve. Sleeves have a groove extending over respective side surfaces. Groove and the inner surface of the respective housing in the modular unit define a coil that can be supplied with a thermoregulating fluid whenever the sleeve is inserted into a modular unit. The modular units can be constrained to one another to define one or more channels for distribution of melted rubber that extend from an injector to one or more discharge nozzles, depending on a desired path. Modularity of the units allows the distributor to have ducts for distribution of melted rubber of a desired geometry. Through holes of the sleeves define corresponding lengths of at least one channel for distribution of melted rubber. Since the sleeves are cooled and the melted rubber flows inside them, the distributor is thermoregulated.