An aim of the present invention is to enable a molten resin to be fed from a hot runner apparatus into preform molding portions of an injection molding mold without a higher temperature and lower viscosity resin being present in a biased manner and to enable preforms having no biased portion of a higher temperature and lower viscosity resin in their circumferential direction.

An introducing runner portion (18) of a hot runner apparatus (9) is bent toward a horizontal runner portion (15) after reaching an elevation plane (A) passing through a position of the horizontal runner portion (15) in an up-and-down direction and continuous with an intermediate portion of the horizontal runner portion (15) in the elevation plane (A).

A production method of a floor for quick side-slide installation includes the following steps: step 1: sorting of floor blanks; step 2: curing of the floor blanks; step 3: sanding of the floor blanks; step 4: cutting-to-thickness of the floor blanks; step 5: surface treatment of the floor blanks; step 6: cutting-to-length and molding of the floor blanks; step 7: spraying of anti-cracking oil on the floor blanks; step 8: plastic encapsulation of the floor blanks; step 9: application of a paint to back surfaces of the floor blanks; and step 10: application of the paint or vegetable oil to the floor blanks. A locking frame is hidden under bosses of a floor blank after being injection-molded, which achieves high locking accuracy and firm assembly.

A hot channel device for guiding an incoming hot melt, in particular a plastic melt, to a gate opening of a mould insert of a tool, which gate opening can be opened and closed again by a movable needle, wherein the hot channel device has a first hot channel region, with a coolable melt transfer region, and a second hot channel region, which are arranged one behind the other in the flow direction of the melt toward the mould insert, wherein the coolable melt transfer region has a melt transfer chamber, which is penetrated by the needle, said needle being guided displaceably in a needle channel so as to be sealed by a needle seal, and the needle channel continues in an aligned manner in a melt channel of the second hot channel region.

An injection molding apparatus comprising:

An actuator having a driver receiving electrical energy or power from an electrical drive, the electrical drive comprising an interface, the electrical drive being housed within or by and actuator housing or being mounted on or to the housing, the housing and the electrical drive being mounted on, to or in close proximity to the heated manifold, a cooling device disposed between the heated manifold and the housing adapted to substantially isolate or insulate at least the electrical drive from communication with heat emanating from the heated manifold or to heat sink or absorb heat communicated or communicable to the electrical drive from the heated manifold or both.

An injection-molding method includes providing an extruding system configured to produce a mixture, a first discharging channel including a first outlet, a second discharging channel including a second outlet, and a molding device including a space and first and second feeding ports communicable with the space and respectively engageable with the first and second outlets; engaging the first outlet with the first feeding port; engaging the second outlet with the second feeding port; injecting the mixture through the first outlet and the first feeding port; and injecting the mixture through the second outlet and the second feeding port.

An insert (10) adapted to be placed at the gate of an injection molding machine around a tip of a molten material injector, is disclosed.

The inset comprises or consists of a cup-shaped first element (40), comprising or consisting of lateral walls (45) that delimit a first opening for housing the injector body and a bottom (44) centrally provided with a second opening (46), and a second element (20), provided with a third central opening (26) having a major dimension that is smaller than that of the second opening (36). The second element (20) is connectable to said bottom (44) so that the second (46) and third opening (26) are aligned.

An injection-molding system includes an extruding system configured to produce a mixture; discharging channels communicable with the extruding system, wherein each of the discharging channels includes an outlet; and a molding device configured to receive the mixture from the outlets and including a space and feeding ports correspondingly engageable with the outlets. An injection-molding method includes providing an extruding system configured to produce a mixture, a first discharging channel including a first outlet, a second discharging channel including a second outlet, and a molding device including a space and first and second feeding ports communicable with the space and respectively engageable with the first and second outlets; engaging the first outlet with the first feeding port; engaging the second outlet with the second feeding port; injecting the mixture through the first outlet and the first feeding port; and injecting the mixture through the second outlet and the second feeding port.

A conditioned jack for actuating a valve pin of an injector for apparatus for injection molding of plastic materials, includes a cylinder having at least one thrust chamber delimited on one side by a first bottom and on the other side by a second bottom, a support of the cylinder for securing the jack to the molding apparatus, and a flow circuit for a conditioning fluid of the jack, which is formed within a bushing which constitutes said second bottom, is separable from the cylinder and is provided with inner and outer annular sealing gaskets of respectively the cylinder and a stem.

An injection molding apparatus includes an injection-molding mold including a fixed mold and a movable mold, the fixed mold having a gate opening into which a molding material flows, the movable mold having a cavity and being configured to be separated from the fixed mold during mold opening; a hot runner including a nozzle having a channel that guides the molding material to the gate opening, and a heater, the hot runner being disposed in the fixed mold; and a control unit that controls a temperature of the heater to adjust a temperature of the hot runner. The control unit controls the temperature of the heater to a first temperature when the molding material is injected from the hot runner to the cavity, and after the injection of the molding material is completed, controls the temperature of the heater to a second temperature that is higher than the first temperature.

An electric heater with an axial opening for holding an object to be heated includes an electric heating element and a clamping sleeve for generating an adjustable, radial force acting in a direction toward an axis of the axial opening. The clamping sleeve of the electric heating device is penetrated by at least one cut, whose width can be changed by means of at least one clamping device. A component of the clamping device is rotatably mounted or can be rotatably mounted relative to the clamping sleeve about an axis of rotation perpendicular to the axis of the axial opening. This component interacts directly or indirectly with the clamping sleeve so that a rotation of the rotatably mounted or rotatably mountable component of the clamping device changes the width of the cut.