A lighting device (1) is provided. The lighting device (1) comprises a cavity (10). The cavity (10) is extending along a longitudinal axis (L) of the lighting device (1). Further, the cavity (10) is defined by an interior surface (11) configured to reflect light impinging upon the interior surface (11) of the cavity (10). The cavity (10) has an opening (12) permitting light inside the cavity (10) to exit the cavity (10). The lighting device (1) further comprises an optical module (20). The optical module (20) is arranged in or at the opening (12) of the cavity (10), and is configured to transmit light impinging upon a surface (21) of the optical module (20) through the optical module (20). The light transmitted through the optical module (20) is emitted from the lighting device (1). The lighting device (1) further comprises a plurality of light emitting elements (31). The light emitting elements (31) are arranged in a succession along the longitudinal axis (L) of the lighting device (1) and arranged in the cavity (10), and are configured to emit first light (41). The first light (41) is impinging on the surface (21) of the optical module (20) without having first impinged on the interior surface (11) of the cavity (10). The light emitting elements (31) are further configured to emit second light (42). The second light (42) is impinging on the interior surface (11) of the cavity (10). The optical module (20) is configured to collimate the first light (41) in a transverse plane. The transverse plane is perpendicular to the longitudinal axis (L) of the lighting device (1). The optical module (20) is further configured to produce collimated light so as to increase the degree of collimation of light, in the transverse plane, transmitted from the optical module (20) as compared to the first light (41) prior to transmission through the optical module. At least one of the interior surface (11) of the cavity (10), the plurality of light-emitting elements (31) and the optical module (20) is or are configured such that the second light (42), reflected by the interior surface (11) of the cavity (10) and subsequently having impinged upon the surface (21) of the optical module (20) and transmitted from the optical module (20), is light for which at least 3% of the total luminous flux is in th

The present invention relates to illumination techniques and a reflection member that receives light from a light source and forms an irradiated area having a substantially polygonal shape in an irradiated plane, and an illumination device, a surface light source device, a display device, electronic equipment and the like using the same.

A backlight module comprises a back plate, a reflective sheet arranged on the back plate and forming a plurality of openings, a plurality of light-emitting elements located in the plurality of openings, at least one optical element arranged on the reflective sheet, and at least a supporting element configured between the back plate and the reflective sheet. The supporting element can move along with the reflective sheet. The supporting element has a base portion and a supporting portion extending from the base portion towards the optical element. The base portion of the supporting element is located between the back plate and the reflective sheet. The supporting portion of the supporting element passes through the reflective sheet to support the optical element. The supporting element is not a fixed design and can move along with the reflective sheet. Therefore, other plates under the reflective sheet do not require openings, which can improve assembly convenience and effectively reduce the mechanism interference caused by the expansion and contraction of the reflective sheet. The invention also provides a display device including the backlight module.

An ultraviolet (UV) curing system is configured to cure a composite structure. The UV curing system includes a plurality of UV light assemblies that are configured to adaptively conform to a shape of the composite structure. A UV curing method is configured to cure a composite structure. The UV curing method includes positioning a UV curing system on the composite structure, and adaptively conforming a plurality of UV light assemblies of the UV curing system to a shape of the composite structure.

The invention relates to a light fixture (100) having: an elongate light source, which is formed by multiple LEDs (60) or LED clusters arranged one behind the other in the longitudinal direction; a primary optical system (20), which is assigned to the light source and is formed by multiple pot-like reflectors (25), which are arranged one behind the other in the longitudinal direction and each widen in a divergent manner from the light source in a light emission direction of the light fixture (100); and a secondary optical system (30), which follows the primary optical system (20) in the light emission direction and is formed by a planar element consisting of a transparent material, wherein the element has light-refractive structures (35).

An example warning device can include: a plurality of light sources forming an array; a plurality of reflectors, with at least one reflector being associated with each of the plurality of lights; at least one lens for each of the plurality of lights; and an optical prism plate that directs light from one or more of the plurality of lights to one of a plurality of far field light spots.

A lighting apparatus includes a printed circuit board. A first light source and a second light source can be mounted on the printed circuit board. A first optical member can receive and redirect light from the first light source, and a second optical member can receive and redirect light from the second light source. A vent aperture can be defined in the printed circuit board, the vent aperture being positioned between the optical members. The apparatus can include first and second thermally conductive sheets thermally coupled to the printed circuit board, the first thermally conductive sheet disposed on a first back side of the first optical member, the second thermally conductive sheet disposed on a second back side of the second optical member. The apparatus can include a housing having a housing vent, the housing vent and the vent aperture defining a first convective path between the optical members.

To provide a reflection member for forming a polygonal irradiated region. Solution: A reflection member for reflecting light emitted from a light source comprises: at least one polygonal cell, the at least one polygonal cell having: a center bottom part which has a polygonal shape in a plan view and in which the light source is disposed; and an inclined part which is inclined from the center bottom part toward the outer edge, wherein the inclined part has: vertex-part inclined surfaces which are provided so as to correspond to the respective vertexes of the polygonal shape; and side-part inclined surfaces which are each provided between the corresponding vertex-part inclined surfaces, and wherein an inclination angle α of at least a part of the vertex-part inclined surfaces is larger than an inclination angle β of the side-part inclined surfaces in a cross-sectional view.

An optical cup which mixes multiple channels of light to form a blended output, the device having discreet zones or channels including a plurality of reflective cavities each having a remote light converting appliance covering a cluster of LEDs providing a channel of light which is reflected upward. The predetermined blends of luminescence materials provide a predetermined range of illumination wavelengths in the output. The remote light converting appliances may be provided as frustoconical elements within frustoconical reflective cavities with a void between the light converting appliances and the associated LEDs.

A phosphor element includes an incident face for an excitation light, a reflecting face opposing the incident face and a side face, and the phosphor element converts at least a part of the excitation light incident onto the incident face into a fluorescence and emits the fluorescence from the incident face. The incident face has an area greater that an area of the reflecting face. The phosphor element includes an inclination region in which an inclination angle of the side face with respect to a vertical axis perpendicular to the incident face is monotonously increased from the reflecting face toward the incident face, viewed in a cross-section perpendicular to the incident face and along the longest dividing line halving the incident face.