The disclosure is directed to a side gate nozzle (1). The side gate nozzle (1) usually comprises a supply block (2), a distribution block (3) and a nozzle block (4) inter-connected to each other in an axial direction (z). The nozzle block (4) comprises at least one nozzle recess (5), in which a nozzle insert (6) is arranged. The nozzle insert (6) is in the axial direction (z) held by an individual set screw (7) directly or indirectly interconnected to the nozzle block (4).

Apparatus for injection moulding of plastic material includes a mould having at least one gate towards a moulding cavity and at least one injector cooperating with the gate. The gate is formed by a gate insert screwed and arranged resting on a centring seat with conical surface of the mould.

An injection molding system and method are disclosed. The injection molding system includes a molding device and injector. The molding device defines a mold cavity and includes an inlet portion in communication with the mold cavity. The injector includes a discharging channel. An end portion of the inlet portion and an end portion of the discharging channel have non-planar end surfaces respectively, which are engageable with each other.

The present disclosure is directed to an injection nozzle for an injection molding device comprising a drive train for at least one closure element arranged movable in a nozzle head in a first direction. The drive train comprises a cam mechanism with a cam head comprising a wedge and at least one side plate. The wedge and the side plate are together arranged moveable in a second direction. Per closure element the wedge comprises at least one first drive surface which interacts with a second drive surface arranged at the closure element at least during closing of the closure element. The at least one side plate comprises a third drive surface which interacts with a fourth drive surface arranged at the closure element at least during opening of the closure element.

The present disclosure is directed to an injection nozzle with a nozzle head including at least one discharge opening for injecting molding material into a mold cavity of a thereto interconnected injection mold and forming therein a molded body. At least one positively controlled closure element movably supported in the nozzle head for closing a communication opening in the connected injection mold. An actuator cylinder comprises a first piston which is interconnected to the closure element. The first piston is arranged movable between a first position, in which the closure element is fully closed, and a second position in which the closure element is fully open. A second piston is interconnected to the closure element, and is arranged movable between a third position in which the second piston is not interconnected to the closure element and a fourth position in which the closure element is limited in an intermediate position.

A side gate nozzle (1) includes a supply block (2), a distribution block (3) and a nozzle block (4) interconnected to each other in an axial direction (z). The nozzle block (4) comprises at least one nozzle recess (5), in which a nozzle insert (6) is arranged. The nozzle insert (6) is in the axial direction (z) held by an individual set screw (7) directly or indirectly interconnected to the nozzle block (4).

A hot runner system includes a manifold having a heater and a manifold channel network extending between a manifold inlet and a plurality of manifold outlets for distributing a molten plastic. A nozzle seated against the manifold and received in a respective manifold outlet has an extension portion received in the respective manifold outlet, a body portion projecting downstream from the extension portion, and a nozzle channel extending through the extension portion and the body portion. The hot runner system further includes a nozzle support seated against the nozzle, the nozzle support including an upstream nozzle support and a downstream nozzle support, the downstream nozzle support is discrete from and in slidable contact with the upstream nozzle support, and the downstream nozzle support having a looser fit with the body portion of the nozzle than that of the upstream nozzle support's fit with the body portion of the nozzle.

A plastic injection mold for the manufacture of fluid-saving devices is disclosed. The mold includes two subassemblies called the fixed part (Side A) and the moving part (Side B). When they are assembled together, these two subassemblies form the mold. When used in a plastic (polymer) injection process, the mold allows for mass production of a fluid-saving device.

The mold is composed of steel plates superimposed on one another, aligned and joined by fastening elements arranged between the plates. The main elements are the cavity, the core, and the forming pins. The forming pins are interchangeable to achieve product flexibility and obtain different models of fluid-saving devices.

A hot runner mold includes a hot runner mold body portion that is fixed to a fixing plate and supplies a molten resin received from a resin inlet to an injection mold, a nozzle receiving portion that is disposed to be inclined with respect to a position orthogonal to the resin inlet of the hot runner mold body portion and is coaxially connected to a nozzle of an injection device that supplies the molten resin, a relay portion that has a resin flow path having a bent portion therein and guides the molten resin from the nozzle receiving portion to the resin inlet, and a regulating portion that is fixed to the fixing plate and regulates movement of the nozzle receiving portion or the relay portion with respect to the hot runner mold body portion.