An apparatus changes the temperature of thermoplastic material in an extruder head to reduce the time for producing an object. The apparatus includes a cooling device located near the one or more nozzles of the extruder head to change the temperature of the thermoplastic material extruded by the extruder head. The apparatus cools the thermoplastic material to enhance the formation of exterior object features. A heater can also be positioned near the nozzle zone to heat the thermoplastic material to reduce the time for raising the viscosity of the thermoplastic material for forming interior regions of the object.

The present invention provides an integral cooling system within an FFF nozzle manifold. The system includes a cooling reservoir formed within the body of the nozzle manifold, adapted to circulate a cooling liquid around the filament chamber and nozzle orifice. The coolant channel is situated to be in close physical proximity to the chamber and orifice, and to be thermally coupled to both via the body of the nozzle manifold. In addition, the interior of the cooling chamber is constructed so as to maximize the available surface area within a given cross-sectional geometry, thereby promoting increase heat transfer between the nozzle manifold and the cooling liquid.

A method for forming an object made of a polymeric material, wherein the polymeric material has a melting temperature (Tf), comprising the following steps: melting the polymeric material; cooling the polymeric material below the melting temperature (Tf); extruding the polymeric material into a tubular shaped body (H); inserting the tubular body (H) into a mould (60) having an internal cavity; closing off the tubular body (H) at a first end thereof; blowing air into the tubular body (H) through a second end, in order that the tubular body (H) adheres to the internal cavity of the mould (60).

A method for forming an object made of a polymeric material, wherein the polymeric material has a melting temperature (Tf), comprising the following steps: melting the polymeric material; cooling the polymeric material below the melting temperature (Tf); extruding the polymeric material into a tubular shaped body (H); inserting the tubular body (H) into a mould (60) having an internal cavity; closing off the tubular body (H) at a first end thereof; blowing air into the tubular body (H) through a second end, in order that the tubular body (H) adheres to the internal cavity of the mould (60).

With a method for producing a two-dimensional or three-dimensional framework (1) with rods (2) of a composite material with fibers and a matrix, which are connected with nodes (3) to at least one other rod (2) and/or another component (29), comprising the steps of: producing the rods (2) out of a composite material, connecting the rods (2) with at least one other rod (2) and/or another component (29) at the nodes (3), the framework (1) should be manufactured inexpensively and reliably by a low technical effort. This object can be solved in a way that the rods (2) are being produced with pultrusion and/or extrusion and a pultrusion unit (6) and/or an extrusion unit (7) is moved in space such that after the pultrusion and/or extrusion the pultruded and/or extruded rods (2) are pultruded and/or extruded in each case at the required position within the framework (1).

The present invention relates to a distribution device for an extruder, comprising at least two conduits leading away from a distribution unit, each conduit having a temperature-control device. The present invention further relates to an extrusion system comprising a distribution device of the above kind and to a method for producing a proteinaceous food item by means of the extrusion system.

The present invention relates to a distribution device for an extruder, comprising at least two conduits leading away from a distribution unit, each conduit having a temperature-control device. The present invention further relates to an extrusion system comprising a distribution device of the above kind and to a method for producing a proteinaceous food item by means of the extrusion system.

A device for producing plastic pipes may include an extruder with a die head and a corrugator, into which a molten plastic tube is introduced by means of the die head to mold the plastic pipe, wherein the corrugator has a molding section, in which molding jaws are guided in pairs in the production direction. In an inlet section of the corrugator, the molding jaws are brought together to form molding jaw pairs towards the start of the molding section, and in an outlet section of the corrugator, the molding jaw pairs are moved apart from each other from the end of the molding section. The guiding apparatus has a guide and/or temperature-control element apparatus having a temperature-control medium channel apparatus through which temperature-control medium can flow, and a guide and/or temperature-control surface apparatus, which faces the outer side of the molding jaws passing through, transferring heat.

A three-dimensional printing nozzle, a three-dimensional printing nozzle assembly, and a three-dimensional printing apparatus are provided. The three-dimensional printing nozzle includes a nozzle body having an inlet and an outlet, a driving unit disposed in the nozzle body, a first heating unit, and a first heat dissipation unit. A particle forming material is adapted to enter the nozzle body from the inlet. The driving unit is configured for pushing the particle forming material to move from the inlet to the outlet. The first heating unit is disposed in the nozzle body for heating and melting the particle forming material and extrudes a melted forming material out of the nozzle body from the outlet through the driving unit. The first heat dissipation unit is disposed in the nozzle body and located between the first heating unit and the inlet to reduce heat transmitted from the first heating unit to the inlet.

A wax melt blank is produced with an extrusion process and intended to later be cut to length into individual wax melts. The wax melt blank includes at least about fifty percent by weight of wax, a fragrance, and up to about fifty percent by weight of a filler. The wax, the fragrance, and the filler are homogeneously dispersed within the wax melt blank.