According to an embodiment, an additive manufacturing apparatus includes a first irradiation unit, and a first emission device. The first irradiation unit is configured to irradiate a material with first light to melt or sinter the material. The first emission device includes a first light source configured to emit the first light, is configured to cause the first light emitted from the first light source to enter the first irradiation unit, and is capable of changing a wavelength of the first light entering the first irradiation unit.

A process for manufacturing a three-dimensional object from a powder by selective sintering the powder using electromagnetic radiation. The powder includes recycled PAEK. In one embodiment, the powder includes recycled PEKK. In one embodiment, the powder includes first recycle PEKK and second recycle PEKK. In one embodiment, the powder consists essentially of recycled PEKK. The process may include the step of maintaining a bed of a selective laser sintering machine at approximately 300 degrees Celsius and applying a layer of the powder to the bed. The average in-plane tensile strength of the three-dimensional object is greater than that of a three-dimension object manufactured by selective sintering using a powder including an unused PEKK powder.

A process for manufacturing a three-dimensional object from a powder by selective sintering the powder using electromagnetic radiation. The powder includes recycled PAEK. In one embodiment, the powder includes recycled PEKK. In one embodiment, the powder includes first recycle PEKK and second recycle PEKK. In one embodiment, the powder consists essentially of recycled PEKK. The process may include the step of maintaining a bed of a selective laser sintering machine at approximately 300 degrees Celsius and applying a layer of the powder to the bed. The average in-plane tensile strength of the three-dimensional object is greater than that of a three-dimension object manufactured by selective sintering using a powder including an unused PEKK powder.

The invention pertains to a molded part (10) with a visible surface and a rear surface (S1, S2), wherein the molded part (10) features: a substrate (20) of hot-pressed fibrous molding material (21); a coating (30) of at least one polymer material (34, 35);
wherein the surface (33) of the coating (30) has at least sectionally a center line average height Ra in the range of 10 to 80 m,
as well as to a method for manufacturing the molded part.

A process for manufacturing a three-dimensional object from a powder by selective sintering the powder using electromagnetic radiation. The powder comprises recycled PAEK. In one embodiment, the powder comprises recycled PEKK. In one embodiment, the powder comprises first recycle PEKK and second recycle PEKK. In one embodiment, the powder consists essentially of recycled PEKK. The process may include the step of maintaining a bed of a selective laser sintering machine at approximately 300 degrees Celsius and applying a layer of the powder to the bed. The average in-plane tensile strength of the three-dimensional object is greater than that of a three-dimension object manufactured by selective sintering using a powder comprising an unused PEKK powder.

A process for manufacturing a three-dimensional object from a powder by selective sintering the powder using electromagnetic radiation. The powder comprises recycled PAEK. In one embodiment, the powder comprises recycled PEKK. In one embodiment, the powder comprises first recycle PEKK and second recycle PEKK. In one embodiment, the powder consists essentially of recycled PEKK. The process may include the step of maintaining a bed of a selective laser sintering machine at approximately 300 degrees Celsius and applying a layer of the powder to the bed. The average in-plane tensile strength of the three-dimensional object is greater than that of a three-dimension object manufactured by selective sintering using a powder comprising an unused PEKK powder.

The invention relates to a process for the heat treatment of poly(arylene ether ketone ketone) powder suitable for laser sintering, and also to the powders resulting from this process.

[Object] A method for manufacturing a three-dimensional object is provided. The method reduces the difference between the amount of build material used and the amount of decorative ink used.

[Means of Realizing the Object] A method for manufacturing a three-dimensional object including an object body portion (A) and a decorative portion (C) is provided. The method includes forming the object body portion (A) from at least decorative ink and build material and forming the decorative portion (C) from the decorative ink. The decorative portion (C) covers the object body portion (A).

[Object] A method for manufacturing a three-dimensional object is provided. The method reduces the difference between the amount of build material used and the amount of decorative ink used.

[Means of Realizing the Object] A method for manufacturing a three-dimensional object including an object body portion (A) and a decorative portion (C) is provided. The method includes forming the object body portion (A) from at least decorative ink and build material and forming the decorative portion (C) from the decorative ink. The decorative portion (C) covers the object body portion (A).

The objective of the present invention is to provide a powder material for a powder bed fusion method, said powder material making it possible to easily sinter or fuse metal particles included in the powder material using a low-energy laser regardless of the material constituting the powder material. The powder material is used in the production of a three-dimensional molded article by selectively irradiating a thin layer of the powder material, which includes metal particles, with a laser light, forming molded article layers formed by sintering or fusing the metal particles, and laminating the molded article layers. The powder material includes porous metal particles formed by binding metal nanoparticles with a binder, and the BET specific surface area of the powder material is 5.010.sup.61.110.sup.8 (m.sup.2/m.sup.3), inclusive.