The disclosure relates to a method for producing an extruded sheet, which includes: a) providing calcium carbonate (CaCO3) powder; b) providing polyvinyl chloride (PVC) powder; c) providing additives as stabilisers, e) heating the mixture until the PVC softens to form a kneadable mass and the CaCO3 at least partially bonds to the PVC; f) cooling the mass; g) conveying the mass to an extruder; h) melting and extruding the mass by means of an extruder and moulding into a sheet by means of a slotted nozzle; i) pressing the still-warm sheet to a desired final thickness by means of at least two calendar rolls; and j) at least one layer of a pigmented lacquer is applied to the upper side; and k) an additional lacquer is applied to the pigmented lacquer to increase the scratch resistance.

The disclosure relates to a method for producing an extruded sheet, which includes: a) providing calcium carbonate (CaCO3) powder; b) providing polyvinyl chloride (PVC) powder; c) providing additives as stabilisers, e) heating the mixture until the PVC softens to form a kneadable mass and the CaCO3 at least partially bonds to the PVC; f) cooling the mass; g) conveying the mass to an extruder; h) melting and extruding the mass by means of an extruder and moulding into a sheet by means of a slotted nozzle; i) pressing the still-warm sheet to a desired final thickness by means of at least two calendar rolls; and j) at least one layer of a pigmented lacquer is applied to the upper side; and k) an additional lacquer is applied to the pigmented lacquer to increase the scratch resistance.

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 material melting device (10) for melting a work material, and discharge of the melted work material, is described. The material melting device (10) comprises a cold part (12) and a hot part (30), and a work material duct (22) for supplying said work material. The work material duct (22) extends at least partially through the cold part (12) to a melting chamber (33) arranged in the hot part (30). The hot part (30) comprises a nozzle duct (34) extending from the melting chamber (33) to a nozzle opening (35) such that melted work material can be flowed from the melting chamber (33) and discharged from the nozzle opening (35). The melting chamber (33) has a cross-sectional area which is larger than the cross-sectional area of the work material duct (22).

The invention relates to a method for mechanically treating clay (4), in particular for producing models, the clay (4) being heated by an extruder, extruded and applied to a surface (8), and to a corresponding device for mechanically treating clay (4), in particular for producing models. The invention is characterised in the device comprises an extruder (6) which is designed to heat and extrude clay (4) for applying to a surface (8).

The invention relates to a calibration device (1) for calibrating a blown film (6), said device comprising; a tubular region (55) with at least one inner wall (92), through which region the blown film (6) can be passed; a liquid reservoir which provides a liquid and which is situated above the tubular region (55); an inlet region, in which the liquid can be introduced into the space between the outer wall of the blown film (6) and the inner wall (92) of the tubular region (55); and a scraper device (117), situated below the tubular region (55), by means of which scraper device at least part of the liquid can be removed from the outer surface. The distance of the liquid-removing regions of the scraper device (117) from the main axis of the blown film (6) can be altered.

A system and method for enclosing the blowing area of a biopolymer blown film production process. The enclosure surrounds the blown film tower and includes at least a climate controller to maintain an optimal temperature for the blown film process.

A system and method for enclosing the blowing area of a biopolymer blown film production process. The enclosure surrounds the blown film tower and includes at least a climate controller to maintain an optimal temperature for the blown film process.

An apparatus for additively manufacturing an article includes a heat block, a nozzle in operable communication with the heat block and configured to receive a feed material, a heat break coupled to the heat block, at least a portion of the heat break extending into the heat block, and a radiator secured to at least one surface of the heat break. Related tools for additively manufacturing a material in a vacuum and related methods are also disclosed.

Methods for improved colorant dispersion in polymer materials using solid-state shear pulverization, as compared to mixing techniques of the prior art, to address concerns relating to colorant agglomeration, plating-out and the like.