The invention provides a method for producing a 3D item (1) by means of fused deposition modelling, the method comprising a 3D printing stage comprising: layer-wise depositing an extrudate (321) comprising 3D printable material (201), to provide the 3D item (1) comprising 3D printed material (202), wherein the 3D item (1) comprises a plurality of layers (322) of 3D printed material (202), wherein the 3D printable material (201) comprises core-shell 3D printable material (201) comprising (i) a core (221) comprising core material (240) and (ii) a shell (222) comprising shell material (250), wherein the core material (240) comprises a core thermoplastic material (241) and core additive material (242), wherein the shell material (250) comprises a shell thermoplastic material (251) and shell particles (252), wherein the shell material (250) is light transmissive for one or more wavelengths in the visible wavelength range, wherein the shell particles (252) comprise specularly reflective particles, wherein the core additive material (242) comprises one or more of diffuse reflective particles, white particles, black particles, colored particles, and dye molecules, and wherein the core material (240) and shell material (250) differ in one or more optical properties selected from the group of color, reflectivity, type of reflectivity, and absorption of light.

The invention provides a method for producing a 3D item (1) by means of fused deposition modelling, the method comprising a 3D printing stage comprising: layer-wise depositing an extrudate (321) comprising 3D printable material (201), to provide the 3D item (1) comprising 3D printed material (202), wherein the 3D item (1) comprises a plurality of layers (322) of 3D printed material (202), wherein the 3D printable material (201) comprises core-shell 3D printable material (201) comprising (i) a core (221) comprising core material (240) and (ii) a shell (222) comprising shell material (250), wherein the core material (240) comprises a core thermoplastic material (241) and core additive material (242), wherein the shell material (250) comprises a shell thermoplastic material (251) and shell particles (252), wherein the shell material (250) is light transmissive for one or more wavelengths in the visible wavelength range, wherein the shell particles (252) comprise specularly reflective particles, wherein the core additive material (242) comprises one or more of diffuse reflective particles, white particles, black particles, colored particles, and dye molecules, and wherein the core material (240) and shell material (250) differ in one or more optical properties selected from the group of color, reflectivity, type of reflectivity, and absorption of light.

A dynamic acoustic jacket device and a dynamic acoustic jacket system, that includes a single piece of material folded into acoustic jacket for covering a lighting fixture, using locking devices or the cut away portion of the device, to quickly and easily install the acoustic jacket over suspension cables so that the acoustic jacket can be lowered and raised over the lighting fixture without the need to be attached thereto.

A dynamic acoustic jacket device and a dynamic acoustic jacket system, that includes a single piece of material folded into acoustic jacket for covering a lighting fixture, using locking devices or the cut away portion of the device, to quickly and easily install the acoustic jacket over suspension cables so that the acoustic jacket can be lowered and raised over the lighting fixture without the need to be attached thereto.

The invention provides a method for producing a 3D item (1) by means of fused deposition modelling, the method comprising a 3D printing stage comprising layer-wise depositing an extrudate (321) from 3D printable material (201), to provide the 3D item (1) comprising 3D printed material (202), wherein the 3D item (1) comprises a plurality of layers (322) of 3D printed material (202), wherein each layer (322) has a layer height (H) and a layer width (W), wherein the 3D printing stage comprises generating a stack (1322) of the layers (322) of the 3D printed material (202), wherein at a fixed first x,y-position the layer height (H) is varied layer by layer for a subset of a total number of layers (322), wherein either (i) the layer height (H) increases for consecutive layers (322) and then the layer height (H) decreases for consecutive layers (322), or (ii) the layer height (H) decreases for consecutive layers and then the layer height (H) increases for consecutive layers (322); and wherein at least part of the 3D printable material (201) comprises light transmissive polymeric thermoplastic material (401).

The invention provides a method for producing a 3D item (1) by means of fused deposition modelling, the method comprising a 3D printing stage comprising layer-wise depositing an extrudate (321) from 3D printable material (201), to provide the 3D item (1) comprising 3D printed material (202), wherein the 3D item (1) comprises a plurality of layers (322) of 3D printed material (202), wherein each layer (322) has a layer height (H) and a layer width (W), wherein the 3D printing stage comprises generating a stack (1322) of the layers (322) of the 3D printed material (202), wherein at a fixed first x,y-position the layer height (H) is varied layer by layer for a subset of a total number of layers (322), wherein either (i) the layer height (H) increases for consecutive layers (322) and then the layer height (H) decreases for consecutive layers (322), or (ii) the layer height (H) decreases for consecutive layers and then the layer height (H) increases for consecutive layers (322); and wherein at least part of the 3D printable material (201) comprises light transmissive polymeric thermoplastic material (401).

The invention provides a 3D printed object (210) and a method of manufacturing such an object (210) by means of fused de-position modelling. The method successively comprises the steps of (i) 3D printing a printable material (120) to create a layer stack (230) of printed material (210), wherein the layer stack (210) bounds a space (240), wherein the layer stack (210) has an inner stack surface (231) and an outer stack surface (232), the inner stack surface (231) facing towards the space (240) and the outer stack surface (232) facing away from the space (240), (ii) providing a heat shrink (250) onto the layer stack (230), wherein the heat shrink (250) has an inner heat shrink surface (251) and an outer heat shrink surface (252), the inner heat shrink surface (251) facing towards the outer stack surface (232) and the outer heat shrink surface (252) facing away from the outer stack surface (232), and (iii) applying heat to shrink (250) the heat shrink so that the inner heat shrink surface (251) is in physical contact with the outer stack surface (232) and the heat shrink (250) is conformal to the layer stack (230). The layer stack (230) is light transmissive, and the heat shrink (250) is arranged to provide an optical effect chosen from the group consisting of refraction, diffraction, reflection, diffusion and conversion. The 3D printed object (210) may be used as a component of a lighting device (600), such as a lampshade.

The invention provides a 3D printed object (210) and a method of manufacturing such an object (210) by means of fused de-position modelling. The method successively comprises the steps of (i) 3D printing a printable material (120) to create a layer stack (230) of printed material (210), wherein the layer stack (210) bounds a space (240), wherein the layer stack (210) has an inner stack surface (231) and an outer stack surface (232), the inner stack surface (231) facing towards the space (240) and the outer stack surface (232) facing away from the space (240), (ii) providing a heat shrink (250) onto the layer stack (230), wherein the heat shrink (250) has an inner heat shrink surface (251) and an outer heat shrink surface (252), the inner heat shrink surface (251) facing towards the outer stack surface (232) and the outer heat shrink surface (252) facing away from the outer stack surface (232), and (iii) applying heat to shrink (250) the heat shrink so that the inner heat shrink surface (251) is in physical contact with the outer stack surface (232) and the heat shrink (250) is conformal to the layer stack (230). The layer stack (230) is light transmissive, and the heat shrink (250) is arranged to provide an optical effect chosen from the group consisting of refraction, diffraction, reflection, diffusion and conversion. The 3D printed object (210) may be used as a component of a lighting device (600), such as a lampshade.

Disclosed is a multilayered image transmitting lampshade manufacturing process and a product thereof. The manufacturing process includes forming, on an inside surface of a hollow light-transmitting lampshade made of light-transmitting glass or light-transmitting plastics, a non-transparent electroplated coating film, using a laser engraving machine to engrave at least one hollowed zone having different shapes and sizes in the non-transparent electroplated coating layer, and finally, conducting nano-coating to form a semi-transparent coating film on an outside surface of the lampshade. The product includes a hollow light-transmitting lampshade having an inside surface coated with a non-transparent electroplated coating layer that is machined with a laser engraving machine to form at least one hollowed zone constituting a pattern and also includes glue applied to fix glitter or light-transmitting color paint between the inside surface of the lampshade and the non-transparent electroplated coating layer, and further includes a semi-transparent nano coating film.

The present disclosure provides a cover for a light source and a method for making a cover for a light source.