An omnidirectional LED filament holder and lighting device comprising the same comprises a filament tree supporting a plurality of linear LED filaments having a twisted orientation relative to a central support stalk of the filament tree. When arranged within a globe of a lighting device, the omnidirectional LED filament holder provides a lighting device providing omnidirectional light emission usable for general lighting applications while providing a desirable aesthetic for the lighting device.

A half-enclosed flexible light strip includes a flexible circuit board, a transparent cover with a half-enclosed structure and a plurality of light sources. The plurality of light sources and the transparent cover are all arranged on the same surface of the flexible circuit board. The light sources are located between the transparent cover and the flexible circuit board. The transparent cover is formed by co-extrusion process and connected to the flexible circuit board. The transparent cover with a half-enclosed structure is formed onto the flexible circuit board by co-extrusion process, the use of glue is reduced, so that the light emitted from the two sides of the transparent cover will not cause color drift problem, and this arrangement ensures the consistency of the luminous effect in all directions, thereby improving the light strip use effect.

A half-enclosed flexible light strip includes a flexible circuit board, a transparent cover with a half-enclosed structure and a plurality of light sources. The plurality of light sources and the transparent cover are all arranged on the same surface of the flexible circuit board. The light sources are located between the transparent cover and the flexible circuit board. The transparent cover is formed by co-extrusion process and connected to the flexible circuit board. The transparent cover with a half-enclosed structure is formed onto the flexible circuit board by co-extrusion process, the use of glue is reduced, so that the light emitted from the two sides of the transparent cover will not cause color drift problem, and this arrangement ensures the consistency of the luminous effect in all directions, thereby improving the light strip use effect.

A lighting apparatus includes a solar plate, a battery, a driver module, a light source, a lens tube, a main housing and a plugging bar. The solar plate converts a sunlight to an electricity. The battery stores the electricity. The driver module converts the electricity stored in the battery to a driving current. The solar plate is placed on a top side of the driver module and the light source is placed on a bottom side of the driver module. The lens tube has a top opening and a bottom opening. The top opening has a larger size than the bottom opening. The top opening is closer to the light source than the bottom opening. A light of the light source is emitted via a lateral lens surface of the lens tube between the top opening and the bottom opening.

An illumination device may include, but is not limited to: a shell portion; and a light projection device disposed at least partially within the shell portion, the light projection device including: at least one light source operably couplable to a power source; and at least one diffraction grating configured to distribute a light beam generated by the at least one light source onto an interior surface of the shell portion.

A linear luminaire includes a linear channel defining an interior space and a linear light inset configured for being inserted into the channel in the interior space. The light inset includes a cover and a printed circuit board fixed to the cover. The printed circuit board supports a plurality of light emitting diodes. The cover base wall includes a translucent portion. The light emitting diodes are arranged for emitting light through the translucent portion. The cover includes two cover connectors, each configured for being snapped into the channel to hold the cover in the interior space. The cover connectors are on an opposite side of the printed circuit board as the translucent portion.

A linear luminaire includes a linear channel defining an interior space and a linear light inset configured for being inserted into the channel in the interior space. The light inset includes a cover and a printed circuit board fixed to the cover. The printed circuit board supports a plurality of light emitting diodes. The cover base wall includes a translucent portion. The light emitting diodes are arranged for emitting light through the translucent portion. The cover includes two cover connectors, each configured for being snapped into the channel to hold the cover in the interior space. The cover connectors are on an opposite side of the printed circuit board as the translucent portion.

A light bulb apparatus includes a head cup, a bottom support, multiple light strips and a bulb shell. The head cup is connected to an external power source. The bottom support is extended from the head cup. Each light strip has a top end and a bottom end. The bottom ends of the light strips are connected to the bottom support. The top ends of the light strips form a top polygonal shape and the bottom ends of the light strips form a bottom polygonal shape. The bottom polygonal shape has a bigger area size than the top polygonal shape. Each light strip has a skewed angle with respect to a middle axis perpendicular to the bottom shape.

An omnidirectional light-emitting bulb shell and a light bulb having the same, comprising a light-transmitting bulb shell, wherein, the light-transmitting bulb shell forms an enclosed space, at least one heat dissipation channel is arranged through the light-transmitting bulb shell, two ends of the heat dissipation channel are communicated with outside of the bulb shell respectively, and at least one LED filament is arranged in the enclosed space on the surface of at least part of the heat dissipation channels that is within the enclosed space. The bulb shell and the light bulb having the same can implements 360 degree omnidirectional illumination with large light-emitting angle and high light-emitting efficiency, and have good heat dissipation performance, thereby increasing the service life of the LED lamp.

The present disclosure discloses a light distribution element and a lamp, the light distribution element is configured to distribute light for a light source, and the light distribution element includes at least two first light distribution modules arranged along a height direction of the light distribution element, the at least two first light distribution modules surround the light source in a circumferential direction, each of the at least two first light distribution modules includes a light incident surface and a light output surface that are away from each other, and the light incident surface is arranged opposite to the light source, each of the at least two first light distribution modules has a divergent light configuration from the light incident surface to the light output surface; and a depression region is between two adjacent first light distribution modules.