A method of recycling a first polymer from a multi-component polymer product may include subjecting the multi-component polymer product that includes a first polymer and at least one additional component to conditions to melt the first polymer; and filtering the at least one additional component from the molten first polymer.

A method for producing a polyester film is provided. The method includes a resin alloy master batch preparation step and a film forming step. The resin alloy master batch preparation step includes melting and kneading a high temperature resistant resin material and a polyester resin material with a twin-screw granulator, and then forming a plurality of resin alloy master batches. In the resin alloy master batch preparation step, a twin-screw temperature of the twin-screw granulator is between 250° C. and 320° C., and a twin-screw rotation speed of the twin-screw granulator is between 300 rpm and 800 rpm. The film forming step includes melting and extruding the resin alloy master batches with to form a polyester film. The polyester film includes a heat resistant layer formed of the plurality of resin alloy master batches so that the heat resistant layer includes the high temperature resistant resin material and the polyester resin material.

A method of printing a hollow part with a robotic additive manufacturing system includes extruding thermoplastic material onto a build platform movable in at least two degrees of freedom in a helical pattern along a continuous 3D tool path with an extruder mounted on a robotic arm, to thereby print a hollow member having a length and a diameter. The method includes orienting the hollow member during printing by moving the build platform based on a geometry of the hollow member wherein the movement of the build platform and the movement of the robotic arm are synchronized to print the part without support structures.

A system and method for thermoplastic composite processing including compressing and heating a thermoplastic composite panel having a plurality of terminal edges. The method further includes heating the thermoplastic composite panel to a melting temperature to create a melt front of the thermoplastic composite panel at a first location and heating the thermoplastic composite panel to the melting temperature in a pre-determined pattern from the first location toward the terminal edges of the thermoplastic composite panel. Extending the melt front toward the terminal edges in this way causes air constrained within the thermoplastic composite panel to escape the thermoplastic composite panel through unmelted portions of the thermoplastic composite panel located between the melt front and the terminal edges. Cooling of the panel may be similarly conducted, cooling a first region and then gradually continuing to cool the panel in a direction toward one or more of the terminal edges.

A method of printing a hollow part with a robotic additive manufacturing system includes extruding thermoplastic material onto a build platform movable in at least two degrees of freedom in a helical pattern along a continuous 3D tool path with an extruder mounted on a robotic arm, to thereby print a hollow member having a length and a diameter. The method includes orienting the hollow member during printing by moving the build platform based on a geometry of the hollow member wherein the movement of the build platform and the movement of the robotic arm are synchronized to print the part without support structures.

A method for rapid heat cycle compression molding comprises placing an assemblage of feed constituents in a mold, placing the mold between two hot platens of a hot press, heating the mold by pressing the two hot platens against the mold, placing the mold between two cold platens of a cold press, cooling the mold by pressing the two cold platens against the mold, and ejecting the part from the mold.

A method for manufacturing an oral care implement comprising a handle, a connector, and a head repeatedly attachable to and detachable from the handle via the connector. The method includes the steps of injection molding of at least a part of the handle having a distal end and a proximal end opposite thereto and comprising a hollow portion; injection molding of at least a part of the connector having an outer lateral surface and a recess therein, the recess forming a cavity within the connector; injection molding of at least a part of the head; inserting the connector into the hollow portion of the handle and fixing the connector therein by gluing, welding, and/or press-fitting.

A fiber-reinforced composite material having at least one reinforcement layer having one or more woven mats, unwoven mats, or bundle of fibers comprising a plurality of reinforcement fibers that has a binder-resin filling at least a portion of the voids of the reinforcement fibers. In some aspects, the binder-resin adheres to the reinforcement fibers and displaces the air voids at the interface between the reinforcement fibers and the binder-resin. The binder-resin has a relatively low viscosity less than at least about 20,000 centipoise at 176° C. and low molecular weight, which allows the reinforcement layer to maintain a low flex modulus while maintaining or increasing tensile modulus. The fiber-reinforced composite material can be utilized in various articles, such as a flexible fiber reinforced hose adapted for conveying fluids under pressure having at least one polymer layer that bonds to the binder-resin of the reinforcement layer, preferably being cross-linkable or cross-linked to the polymer layer.

A method for printing a three-dimensional part with an additive manufacturing system, which includes providing a part material that compositionally has one or more semi-crystalline polymers and one or more secondary materials that are configured to retard crystallization of the one or more semi-crystalline polymers, where the one or more secondary materials are substantially miscible with the one or more semi-crystalline polymers. The method also includes melting the part material in the additive manufacturing system, forming at least a portion of a layer of the three-dimensional part from the melted part material in a build environment, and maintaining the build environment at an annealing temperature that is between a glass transition temperature of the part material and a cold crystallization temperature of the part material.

The invention provides an amorphous copolymerized polyester raw material for a film, wherein the copolymerized polyester raw material (1) contains ethylene terephthalate as a main constituent component, and neopentyl glycol by 15-30 mol % when a total amount of glycol component in a total polyester resin component is taken as 100 mol %, (2) contains a constituent unit derived from diethylene glycol by 7-15 mol % in the total amount of glycol component 100 mol % in the total polyester resin component, (3) has an intrinsic viscosity of 0.60 dl/g or more and less than 0.70 dl/g, and (4) has a glass transition temperature of 60-70° C. The invention also provides a heat-shrinkable polyester-based film containing the amorphous copolymerized polyester raw material, as well as a heat-shrinkable label and a packaging bag.