A method for 3D printing a 3D item (10), the method comprising providing a filament (320) of 3D printable material (201) and printing during a printing stage said 3D printable material (201) on a substrate (1550), to provide said 3D item (10), wherein the printing stage comprises (a) providing a layer (405) comprising particles (410) on the substrate (1550), wherein the particles (410) have a main axis (A1) having a main axis length (LI), and a minor axis (A2) having a minor axis length (L2), wherein the main axis length (LI) and the minor axis length (L2) have a first aspect ratio of at least 5, wherein in average the main axes (A1) of said particles (410) are configured parallel to a tangential plane (P) to the substrate (1550), wherein said particles (410) comprise light reflective material (411), and (b) printing said 3D printable material (201) on said layer (405) on the substrate (1550) to provide said 3D item (10) comprising said layer (405).

A filler-resin composite includes a filler layer in which filler is assembled, a resin layer in which resin is charged in at least one end portion of the filler layer in the thickness direction and a distal end of the one end portion of the filler layer is exposed, and a release member laminated on the resin layer, wherein the release member can be released from the resin layer.

The invention relates to a hull of a vessel having characteristic surface properties, allowing an increase in surface runoff while benefiting from an inherent anti-fouling property and an original aesthetic appearance. Furthermore, the invention allows the incorporation of said outer composite envelope into the structure of the hull, thereby preventing delamination problems and inherently providing a vessel hull with the above-mentioned properties.

The invention relates to a hull of a vessel having characteristic surface properties, allowing an increase in surface runoff while benefiting from an inherent anti-fouling property and an original aesthetic appearance. Furthermore, the invention allows the incorporation of said outer composite envelope into the structure of the hull, thereby preventing delamination problems and inherently providing a vessel hull with the above-mentioned properties.

The invention relates to a metal polymer composite having properties that are enhanced or increased in the composite. Such properties include color, magnetism, thermal conductivity, electrical conductivity, density, improved malleability and ductility and thermoplastic or injection molding properties.

The invention relates to a metal polymer composite having properties that are enhanced or increased in the composite. Such properties include color, magnetism, thermal conductivity, electrical conductivity, density, improved malleability and ductility and thermoplastic or injection molding properties.

The invention relates to a process for preparing an electrically conductive composite film, in particular in the form of a self-supported film or of a prepreg, comprising at least one thermoplastic polymer resin and electrically conductive particles chosen from a) graphene, carbon nanotubes, carbon nanofibres, and mixtures thereof; and b) filiform metal nanoparticles; to a process for preparing an electrically conductive laminated composite structure comprising such an electrically conductive composite film; to said electrically conductive composite film, to said electrically conductive laminated composite structure, and also to the uses thereof.

The invention relates to a process for preparing an electrically conductive composite film, in particular in the form of a self-supported film or of a prepreg, comprising at least one thermoplastic polymer resin and electrically conductive particles chosen from a) graphene, carbon nanotubes, carbon nanofibres, and mixtures thereof; and b) filiform metal nanoparticles; to a process for preparing an electrically conductive laminated composite structure comprising such an electrically conductive composite film; to said electrically conductive composite film, to said electrically conductive laminated composite structure, and also to the uses thereof.

A system for creating a feedstock line for additive manufacturing of an object comprises a prepreg-tow supply, a prepreg-tow separator, an optical-direction-modifier supply, a combiner, and at least one heater. The prepreg-tow supply dispenses a precursor prepreg tow, comprising elongate filaments and resin. The prepreg-tow separator separates the precursor prepreg tow into individual elongate filaments at least partially covered with the resin. The optical-direction-modifier supply dispenses optical direction modifiers to the elongate filaments. When electromagnetic radiation strikes the outer surface of the optical direction modifiers, at least a portion of the electromagnetic radiation departs the outer surface at an angle. The combiner combines the elongate filaments and the optical direction modifiers into a derivative prepreg tow. At least the one heater heats the resin to cause wet-out of the optical direction modifiers and the elongate filaments in the derivative prepreg tow by the resin.

A system for creating a feedstock line for additive manufacturing of an object comprises a prepreg-tow supply, a prepreg-tow separator, an optical-direction-modifier supply, a combiner, and at least one heater. The prepreg-tow supply dispenses a precursor prepreg tow, comprising elongate filaments and resin. The prepreg-tow separator separates the precursor prepreg tow into individual elongate filaments at least partially covered with the resin. The optical-direction-modifier supply dispenses optical direction modifiers to the elongate filaments. When electromagnetic radiation strikes the outer surface of the optical direction modifiers, at least a portion of the electromagnetic radiation departs the outer surface at an angle. The combiner combines the elongate filaments and the optical direction modifiers into a derivative prepreg tow. At least the one heater heats the resin to cause wet-out of the optical direction modifiers and the elongate filaments in the derivative prepreg tow by the resin.