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.

A low beam optical module includes a lens, a light-shielding sheet and at least one light concentrating portion. The light-shielding sheet includes a light-shielding sheet body. An upper edge of a front end of the light-shielding sheet body comprises a low beam cutoff line structure. A front end surface and the rear end surface of the light-shielding sheet body are transparent. The light concentrating portion is connected to a rear end of the light-shielding sheet. The lens is arranged in front of the light-shielding sheet, and an outer contour surface of the at least one light concentrating portion is engaged with a lower surface of the light-shielding sheet body—the light-shielding sheet body can receive emitted light of the light concentrating portion and refract the light from the front end surface to the lens. The projected light forms a low beam region III beam shape. A low beam illumination module, a vehicle lamp and a vehicle includes the low beam optical module.

A low beam optical module includes a lens, a light-shielding sheet and at least one light concentrating portion. The light-shielding sheet includes a light-shielding sheet body. An upper edge of a front end of the light-shielding sheet body comprises a low beam cutoff line structure. A front end surface and the rear end surface of the light-shielding sheet body are transparent. The light concentrating portion is connected to a rear end of the light-shielding sheet. The lens is arranged in front of the light-shielding sheet, and an outer contour surface of the at least one light concentrating portion is engaged with a lower surface of the light-shielding sheet body—the light-shielding sheet body can receive emitted light of the light concentrating portion and refract the light from the front end surface to the lens. The projected light forms a low beam region III beam shape. A low beam illumination module, a vehicle lamp and a vehicle includes the low beam optical module.

A lamp is portable and provided. The lamp includes an adjustable lamp body; a lamp control assembly; and a lamp positioning mechanism. The adjustable lamp body is arranged on the lamp control assembly, and the lamp control assembly is arranged inside the lamp positioning mechanism. The adjustable lamp body includes at least one folding part, and the folding part includes two symmetrically arranged outer folding parts and two symmetrically arranged inner folding parts. The inner folding parts are respectively arranged between two ends of each outer folding part. The lamp control assembly includes a control box and a positioning plate respectively arranged at both ends of the adjustable lamp body. There are further provided a lamp belt and a handle body. The control box can adjust and position an angle through the handle body.

A lamp is portable and provided. The lamp includes an adjustable lamp body; a lamp control assembly; and a lamp positioning mechanism. The adjustable lamp body is arranged on the lamp control assembly, and the lamp control assembly is arranged inside the lamp positioning mechanism. The adjustable lamp body includes at least one folding part, and the folding part includes two symmetrically arranged outer folding parts and two symmetrically arranged inner folding parts. The inner folding parts are respectively arranged between two ends of each outer folding part. The lamp control assembly includes a control box and a positioning plate respectively arranged at both ends of the adjustable lamp body. There are further provided a lamp belt and a handle body. The control box can adjust and position an angle through the handle body.

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 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 plurality of layers (322) comprises a stack (1300), wherein the stack (1300) comprises a first layer (1322) and a second layer (2322), wherein the method comprises:—3D printing the first layer (1322) and subsequently the second layer (2322) while providing a plurality of modulations (340) in a z-direction in at least one of the first and second layers (1322, 2322), thereby defining a plurality of openings (354) between the first and second layers (1322, 2322).

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 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 plurality of layers (322) comprises a stack (1300), wherein the stack (1300) comprises a first layer (1322) and a second layer (2322), wherein the method comprises:—3D printing the first layer (1322) and subsequently the second layer (2322) while providing a plurality of modulations (340) in a z-direction in at least one of the first and second layers (1322, 2322), thereby defining a plurality of openings (354) between the first and second layers (1322, 2322).

The present invention provides a crystal lampshade, which belongs to the technical field of lampshade. The crystal lampshade comprises a hanging rod assembly and a lampshade assembly. When in use, the crystal slabs are respectively inserted between the upper cover and the lower cover, and then the hanging bracket is threadedly sleeved onto the hanging bracket through the pressing sleeve, the pressing frame is sleeved in the hanging bracket, a lower end of the hanging bracket passes through the lower cover, installing a decorative cover, and rotating the pressing sleeve, and the pressing frame is gradually pressed onto the upper side of the upper cover by the pressing sleeve, the decoration cover tightly presses against the lower side of the lower cover, thus fixing and limiting the positions of the upper cover and the lower cover, and stabilizing the crystal slabs.

The present invention concerns a lamp (1) having a number of plates (3, 4, 5). The plates (3, 4, 5) are moveable between a position where the plates (3, 4, 5) form a common outer surface and a position where the plates (3, 4, 5) are separated from each other. By means of the plates the shape and appearance of the lamp (1) may be amended between having the form of for instance a closed sphere and a more or less open form. The plates (3, 4, 5) are placed on upper and lower curved arms (17, 26). The curved arms (17, 26) are connected to an upper ring (10) and a lower ring (9). The curved arms (17, 26) are moved by movement of the lower ring (9) towards and away from the upper ring (10).

A decorative sleeve for receiving or placing around a light source such as a traditional or flameless candle. The sleeve includes a flexible sheet of translucent or transparent material having a surface image thereon and having opposing first and second edges and a locking system. The locking system is configured to smoothly connect the first and second edges to form the sheet into a sleeve configuration. The locking system may be disconnected by a user to allow for flat storage of the sheet, and then may be reconnected by the user at a later time when the sleeve is used again.