A wood-grained polymer substrate includes a plurality of layers of different colors. The substrate is formed into elongated boards and used in the production of various end products similar to natural wood. Methods for producing the wood-grained polymer substrate are also provided.

The present invention relates to a shape forming apparatus and a control method for the shape forming apparatus, wherein the shape forming apparatus may comprise a plurality of spray units which evenly spray forming materials having different colors from one another; and a shape forming unit in which a shape is formed from the evenly-sprayed forming materials having different colors from one another.

The present disclosure provides additive manufacturing methods that include depositing onto a substrate a material including a blend of a mechanochromic molecule and a matrix polymer; and fusing the material to provide an article. The mechanochromic molecule has a first end and a second end and includes at least one polymer chain covalently bound to each end.

The present description discloses a 3D printing pen and a use method therefor. A pen body comprises a nozzle and a filament feeding channel through which a filament passes is formed in the pen body. The pen body further comprises a dyeing mechanism, wherein the dyeing mechanism includes a driving mechanism and a dyeing member, and the driving mechanism configured to drive the dyeing member to dye the filament; a filament feeding mechanism configured to convey the filament to the nozzle; a heating element configured to heat and melt the filament; and a stirring mechanism configured to stir the molten filament.

The invention relates to a process for extracting polyester from packaging. In particular, the invention relates to packaging comprising one or more dyes such as black packaging. The claim process uses a two stage extraction process to convert waste polyester in clean, reusable polyester.

The invention relates to a process for extracting polyester from fabric. In particular, fabric comprising polyester and one or more dyes. The claimed process uses a multistage mechanism to separate dyes from polyester containing garments and reconstitute the polyester.

A glass fiber fabric is impregnated with a colored resin having an opacifying property, a colored resin layer formed from the colored resin is provided on a first face of the glass fiber fabric, a transparent resin layer becoming transparent after being cured is provided on a second face of the glass fiber fabric, and thus a prepreg is formed.

A three-dimensional printing kit can include a powder bed material and a fusing agent to selectively apply to the powder bed material. The powder bed material can include polymer particles and a thermochromic additive. The thermochromic additive can be chemically stable at a melting point temperature of the polymer particles, and the thermochromic additive can exhibit a color change at a color transition temperature that is below the melting point of the polymer particles. The fusing agent can include water and a radiation absorber to absorb radiation energy and convert the radiation energy to heat.

To provide a polycarbonate resin composition excellent in the surface hardness, the heat resistance, the moldability and the flame retardancy. A polycarbonate resin composition comprising at least a polycarbonate resin (a) and a polycarbonate resin (b) having structural units different from the polycarbonate resin (a), which satisfies the following requirements: (i) the pencil hardness of the polycarbonate resin (a) as specified by ISO 15184 is higher than the pencil hardness of the polycarbonate resin (b) as specified by ISO 15184; (ii) the glass transition point Tg(a) of the polycarbonate resin (a) and the glass transition point Tg(b) of the polycarbonate resin (b) satisfy the relation of the following (Formula 1):
Tg(b)−45° C. <Tg(a)<Tg(b)−10° C.  (Formula 1):
and (iii) the pencil hardness of the polycarbonate resin composition as specified by ISO 15184 is higher by at least two ranks than the pencil hardness of the polycarbonate resin (b) as specified by ISO 15184.

The present disclosure provides a print head apparatus and method for printing a multi-coloured three-dimensional object. The apparatus separately receives at least two filaments in a cold section, separately feeds the at least two filaments in a transition section, and heats the at least two filaments in a hot section. The hot section includes a combiner tube to combine the at least two filaments, which are then mixed together in a mixing chamber by a mixing shaft. The molten filament mixture is then extruded out of a nozzle. The print head apparatus further includes lifter discs that can lift the mixing shaft out of the chamber, creating a negative pressure in the chamber and sucking the remaining molten filament from the nozzle upwardly and back into the apparatus to reduce oozing and stringing.

Provided is an apparatus for manufacturing a three-dimensional object that may allow a support material to land on a table before a modeling material irrespective of the moving direction of a carriage. The apparatus includes a modeling material head that ejects an ink for object shaping, support material heads that eject an ink for supporting the three-dimensional object, color ink heads that eject color inks, curing units for curing the ejected inks, and a flattening roller unit with a flattening roller used to flatten surfaces of the ejected inks. In the apparatus, one of the curing units, the flattening roller unit, one of the support material heads, the modeling material head, the color ink heads, the other support material head, and the other curing unit are arranged and mounted in the carriage in the mentioned order from one side to the other in the main scanning direction.