Provided are an injection molding machine and an injection molding method. An injection molding machine includes: a plasticizing unit which rotates a screw to plasticize a molding material inside a plastication cylinder, and an injection unit. The injection unit has: a plunger reciprocally moving inside an injection chamber, and an injection driving device reciprocally moving the plunger. By driving the injection driving device to move the plunger backward and forward inside the injection chamber, and driving a rotary driving device to alternately rotate the screw in a normal rotation direction and a reverse rotation direction, the molding material is controlled to reciprocate between the plastication cylinder and the injection chamber.

An apparatus and method for making molded products for marine, automotive, recreational, and other applications. The apparatus and method for making the molded products generally includes a closed mold and an inline mixer for adding a catalyst to a filled resin. The method may include adding a cotton material to a resin to create the filled resin, adding a catalyst to the filled resin, and mixing the catalyst and the filled resin to create a catalyzed, filled resin. The method may also include adding the catalyzed, filled resin to a mold and allowing the catalyzed, filled resin to harden in the mold.

The invention relates to a polymer blend comprising 15 to 70 Wt. % of polyvinyl alcohol (PVOH) and/or of a PVOH copolymer as well as 30 to 85 Wt. % of a further polymer, to a method for preparing a polymer blend, to the use of a polymer blend for producing a packaging material and to a packaging material. The packaging material obtained from the polymer blend is characterized in particular by a low gas permeability and can be produced by means of cost-effective methods.

The invention relates to a high-pressure mixing, dosing and recirculation head for injection or casting reaction molding, said high-pressure mixing, dosing and recirculation head comprising a head body, a mixing chamber, obtained in the head body wherein a valve element or mixing valve slides and in fluid communication with a supply duct, and a self-cleaning element comprising a scraping portion, said self-cleaning element being structured to slide in said supply duct, as well as comprising an apparatus for controlling and commanding mixing, supply and recirculation comprising a plurality of sensors and transducers mounted on board of the head body and of the components parts of the head connected thereto to detect and transform representative physical quantities of at least one operational status of said high-pressure mixing, dosing and recirculation head into electrical signals and an electronic control and storing system adapted to synchronously control and scan said sensors and transducers and adapted to receive and process said electrical signals indicative of said at least one operational status, at the beginning and during the operational phases of said high-pressure mixing, dosing and recirculation head to compare them with each other and with electrical signals representative of a predetermined reference operational status. The invention also relates to a high-pressure mixing, dosing and recirculation method for injection or casting reaction molding.

The present disclosure provides an injection machine for a recycled plastic injection molding system. The injection machine comprises a supplying system configured to drive plastics from an entry end to downstream of receiving route, a heating system disposed to downstream of the supplying system and configured to melt plastics and drive plastics to the downstream of receiving route, and a buffer system disposed to downstream of the heating system and configured to be a receiving state and a supplying state. When the buffer system is in the receiving state, the buffer system is configured to receiving plastics from the heating system. When the buffer system is in the supplying state, the buffer system is configured to drive plastics to downstream of the receiving route.

A mixing extruder for an injection molding machine includes a barrel unit and an extruder screw. The barrel unit includes an extruder tube. The extruder screw includes a screw rod, a helical mixing channel, and a helical gas flow channel communicating with the helical mixing channel. The helical mixing channel and helical gas flow channel both extend around the screw rod. The helical mixing channel extrudes a paste outwardly from a material discharge opening formed at an end of the extruder tube, whereas the helical gas flow channel connects a suction pump through a gas discharge channel formed in the extruder tube oppositely of the material discharge opening.

A molding apparatus includes a machine base, a feeding unit, a material reflow preventing device and a pair of molds. The material reflow preventing device includes a material conduit and a heating unit. The material conduit includes inlet and outlet ports at two opposite ends, inner and outer peripheral surfaces radially opposite to each other, and a low-temperature conduit section, first, second and third heating conduit sections interposed between the inlet and outlet ports. The inner peripheral surface has a spiral groove which extends from inlet port to the outlet port. The heating unit is disposed to heat the material conduit and control the different temperatures in the sections. The reflow of a fluid-state material along the spiral groove is gradually reduced and suspended and is solidified in the low-temperature conduit section.

An optical precision mold machining device is mountable on a chuck of an ultraprecision machining apparatus to perform an aspherical molding process by a cutting tool, and includes a fixture gripped by jaws of the chuck and having positioning holes in a matrix arrangement, a plurality of fasteners extending through the corresponding positioning holes, and a mold including a retained surface with locking holes for insertion of the fasteners, and a mold surface portion having a sprue, a runner and multiple mold bases. Each mold base has sub-runners in communication with the runner. An injection direction of the sprue is parallel to an initial running direction of the runner. The mold is moved with the fixture relative to the cutting tool to a predetermined machining position where each mold base is machined to form therein a cavity with an aspherical cross-section.

A mechanism for mixing a supercritical fluid and a polymer raw material melt provided by the present invention includes a hot-melting unit, a mixing unit, and a supercritical fluid supplying unit. The mixing unit, independently of the hot-melting unit, receives a polymer melt from the hot-melting unit and a supercritical fluid from the supercritical fluid supplying unit, respectively, and mixes the polymer melt and the supercritical fluid into a homogenous single-phase solution. The hot-melting unit is provided with a pushing member for pushing a polymer raw material. The mixing unit is provided with a mixing rotor for mixing the polymer melt and the supercritical fluid.

In a method for operating an injection moulding machine in the absence of a backflow barrier, plastic melt is injected by a plasticising device into a cavity in a screw antechamber of a plasticising screw adapted to rotate about a longitudinal axis and to move translationally by a drive unit during an injection phase and a holding-pressure phase. A rotational drive of the drive unit is controlled such that a speed of the plasticising screw causes overlay of a backflow of the plastic melt from the screw antechamber back into screw threads of the plasticising screw by an opposing delivery flow as a result of a rotation of the plasticising screw due to a translational injection movement of the plasticising screw. A differential flow is established from the backflow and the opposing delivery flow and influenced at least during the injection phase by influencing the speed of the plasticising screw.