A lighting module (1) for connecting to a luminaire, the lighting module extending along a longitudinal axis (LA) and comprising: a base (3) for connecting the lighting module (1) to a socket (11) of the luminaire (10); a central body (4) carrying at least a first light source (21) and a second light source (22), wherein the first light source (21) is configured to emit first light having a first light distribution with a first main direction pointing away from the longitudinal axis (LA), and the second light source (22) is configured to emit second light having a second light distribution with a second main direction pointing away from the longitudinal axis (LA), the first and second main directions being different from one another; and an optical element (6) including at least one optical portion (61) and a cover portion (62) extending all around the central body (4) and said optical element (6) being rotatable about the longitudinal axis (LA) in relation to the central body (4), the at least one optical portion (61) having an optical property, such that the optical portion (61) is configured to affect light emitted from at least one of the light sources, the at least one optical portion (61) extends in an angular area around the longitudinal axis (LA), and the cover portion (62) is configured not to affect light emitted from the remaining sources.

An LED-filament includes a light-transmissive substrate; a first array of LED chips on a front face of the substrate; a second array of LED chips on the front face of the substrate; a first photoluminescence arrangement covering the first array of LED chips; and a second photoluminescence arrangement covering the second array of LED chips; where the first array of LED chips and the first arrangement generate light of a first color temperature and the second array of LED chips and the second arrangement generate light of a second color temperature.

The invention provides a light generating device (1000) comprising an LED filament (100), wherein the LED filament (100) comprises a support (105), a set (107) of solid state light sources (110), and an encapsulant (160), wherein: (I) the LED filament (100) has a length axis (108) having a first length (L1); (II) the solid state light sources (110) are arranged over the first length (L1) of the LED filament (100) on the support (105), wherein the solid state light sources (110) are configured to generate light source light (111); (III) the encapsulant (160) encloses at least part of each of the solid state light sources (110) of the set (107) of solid state light sources (110), wherein the encapsulant (160) comprises a luminescent material (200) configured to convert at least part of the light source light (111) into luminescent material light (201); (IV) the light generating device (1000) is configured to generate device light (1001) comprising one or more of (i) the light source light (111) and (ii) the luminescent material light (201); (V) for each of the solid state light sources (110) of the set (107) of solid state light sources (110) applies that relative to a first virtual plane (171) parallel to the length axis (108) and intersecting with the solid state light source (110) the encapsulant (160) is asymmetrically configured relative to the first virtual plane (171).

An improved light assembly includes aligned directional light sources mounted one behind another. A distal one of the light sources occludes light emitted from a proximal one of the light sources. A reflector is interposed between the light sources, with a convex surface facing the proximal one of the light sources. Thus, the light assembly projects a light field extending at least through an 180 hemisphere, and up to about 270 backwards from the forward orientation of the light field, well-illuminating lateral approaches to the assembly.

A medical lighting device for illuminating an operative field, which device includes light-emitting diode (LED) light sources that cooperate with collimator optical systems to light the operative field. LEDs are mounted on a flat printed circuit board so that their illumination axes (B) passing through the collimator optical systems (7) have different angular orientations. The printed circuit board (6) may be cut out to form tongues, each of which is flexible and has a free end carrying an LED. Each tongue can be deformed under stress in such a manner that its free end is oriented substantially perpendicularly to the illumination axis (B).

The present invention discloses a light emitting device. The light emitting device includes a housing, a first light emitting module and a second light emitting module. The first light emitting module is provided with a first light emitting area and is disposed on the housing. The second light emitting module is provided with a second light emitting area and is disposed on the housing and surrounds the first light emitting module. A first luminance in the first light emitting area is higher than a second luminance in the second light emitting area, and the first luminance and the second luminance are separately controlled.

To efficiently illuminate a wide area, an illumination apparatus includes a housing, a light emitter, and a light-transmissive member supported by the housing. The housing has an outer surface including a first outer surface and a second outer surface adjacent to the first outer surface. The second outer surface faces in a direction different from a direction in which the first outer surface faces. The light emitter is operable with power supplied from a battery pack. The light-transmissive member is transmissive to at least part of light from the light emitter and extends on the first outer surface and on the second outer surface.

A solid state lighting lamp (10) is disclosed comprising a plurality of heatsink modules (40) each extending in alignment with a central axis (15) of the lamp, each heatsink module carrying a plurality of solid state lighting elements (50); and a body (20) extending in alignment with said central axis and delimiting an inner volume of the lamp, wherein the heatsink modules are affixed to said body. The body is the optical housing, i.e. the light exit window of the lamp.

A basic framework for constructing an LED illumination device using standard components is provided. The standard components includes light emitting modules, a power supply connecting module, and a supporting system. Each of the light emitting module includes an LED light source integrated with a chip and a heat sink, a color temperature adjusting module, and an optical lens. The power supply connecting module includes a plurality of power supply modules with different voltage output sockets, light source bases on which the light emitting modules are assembled, power supply connectors electrically connecting the light source bases and the power supply modules and circuit connectors electrically connecting two adjacent light source bases. The supporting system includes a plurality of connecting blocks of building block-type connecting structures and rib parts.

An LED tube lamp comprises a lamp tube, two light boards disposed in the lamp tube having a plurality of light sources mounted thereon, two lamp caps respectively disposed at both ends of the lamp tube and having a power supply disposed in the lamp caps, and a support unit. The power supply comprises a circuit board. The support unit is configured to fix the light board and comprises a main body and a support arm. The support arm is disposed on the main body and abutted to the inner surface of the lamp tube, so that the support unit can support the inner surface of the lamp tube.