A dynamic lunar eclipse lamp is provided, which includes a blocking piece including a transparent area and a circular opaque area, the opaque area is provided at a non-central position of the blocking piece; an imaging lens provided on one side of the blocking piece, one end of the imaging lens is provided with a Fresnel lens, a non-central position on the Fresnel lens is provided with an image, and the imaging lens is configured to project the image onto a non-central position on the blocking piece, a position of the image projected by the imaging lens corresponds to a position of the opaque area on the blocking piece; a rotary drive component connected to the Fresnel lens and configured to drive the Fresnel lens to rotate; and a light source component, the lamp is caused to form a lunar eclipse effect, a crescent or a half-moon display effect.

Illumination system (1) for a vehicle, including at least one lighting device (2), including at least two, individually controllable, light sources (3a, 3b), and a lens element (4), arranged downstream of the two light sources, and a vehicle body component (5). The lens element is configured to emit a first light bundle and a second light bundle towards the vehicle body component, respectively. The vehicle body component includes an opaque section (6) and a plurality of transparent elements (7), embedded within the opaque section. The plurality of transparent elements is defined by at least one parent-group (PG) of transparent elements (7, 7), said PG is divided into at least two sub-groups (SG). The lens element is configured to redirect the first light bundle towards the first sub-group (SG1) of transparent elements and to redirect the second light bundle towards the second sub-group (SG2) of transparent elements.

A novel lighting device is provided which projects two simultaneous yet distinct lighting effects to its surrounding areas from a central mounted and covered light source, firstly illuminating a proximate surface directly by the light source and by reflection of a cover, and secondly light is remotely provided by optically conductive materials which transmit and project light, such that the central light source projects onto proximate surface areas directly and by reflection, and light projects remotely and outwardly, carried from said source by light transmission utilizing optically conductive materials.

An LED meteor light for 360-degree illumination and a method therefor. The LED meteor light includes a plurality of LED meteor light units. Each LED meteor light unit is free of a PCB but includes a hood body. A first bare conducting wire with certain rigidity and a second bare conducting wire with certain rigidity, parallel to each other, are at least arranged inside the hood body. A plurality of LED luminous bodies are arranged in sequence inside the hood body along a direction of the first bare conducting wire with certain rigidity and the second bare conducting wire with certain rigidity. Each LED luminous body is connected to the two bare conducting wires through a first connecting wire and a second connecting wire. The present disclosure facilitates 360-degree illumination without a PCB.

A grating-sheet insert module and a laser lamp are disclosed. The grating-sheet insert module includes an insert tongue, defining a mounting hole extending through the insert tongue and an avoiding groove in communication with the mounting hole, the avoiding groove extending to an edge of the insert tongue; and a grating insert, arranged in the mounting hole, in contact with a hole wall of the mounting hole, configured to be rotatable around a central axis of the mounting hole, the grating insert including a grating sheet configured to enable light entering the mounting hole to transmit therethrough.

Illumination system (1) for a vehicle, including at least one lighting device (2), including at least two, individually controllable, light sources (3a, 3b), and a lens element (4), arranged downstream of the two light sources, and a vehicle body component (5). The lens element is configured to emit a first light bundle and a second light bundle towards the vehicle body component, respectively. The vehicle body component includes an opaque section (6) and a plurality of transparent elements (7), embedded within the opaque section. The plurality of transparent elements is defined by at least one parent-group (PG) of transparent elements (7, 7), said PG is divided into at least two sub-groups (SG). The lens element is configured to redirect the first light bundle towards the first sub-group (SG1) of transparent elements and to redirect the second light bundle towards the second sub-group (SG2) of transparent elements.