A lighting module disclosed in an embodiment comprises: a substrate; a light-emitting element arranged on the substrate; and a resin member arranged on the substrate and the light-emitting element. The resin member comprises a plurality of side surfaces and an exit surface on the upper portion thereof. The plurality of side surfaces of the resin member comprise a first side surface adjacent to the light emitting device, a second side surface facing the first side surface, and third and fourth side surfaces arranged between the first and second side surfaces so as to face each other. The exit surface of the resin member comprises a light extraction structure having a large length in a first direction and having a concavo-convex pattern in a second direction that is perpendicular to the first direction. The light emitting device comprises an exit area corresponding to a part of the second side surface in the first direction. The thickness of the second side surface, in connection with the resin member, may be smaller than the thickness of the first side surface.

A light apparatus is mounted to a surface of a building and comprises: at least one elongate mounting member engaged to the surface; spaced-apart brackets mounted to the at least one elongate mounting member and extending forward therefrom; at least one light source mounted to a plurality of the spaced apart brackets; a forward trim mounted to the spaced-apart brackets; a lower trim mounted to the spaced-apart brackets; and a passageway. The passageway passes at least one of: a fluid line; an optical fiber; a communications line; and a power line not powering the at least one light source.

The invention provides a lighting device (1) comprising a luminescent element (5) comprising an elongated light transmissive body (100), the elongated light transmissive body (100) comprising a side face (140), wherein the elongated light transmissive body (100) comprises a luminescent material (120) configured to convert at least part of a light source light (11) selected from one or more of the UV, visible light, and IR received by the elongated light transmissive body (100) into luminescent material radiation (8). The invention further provides such luminescent element per se.

A cabinet and a kit for retrofitting a cabinet are disclosed. The cabinet includes a stationary box, at least one moveable wing attached to the stationary box and configured to open and close relative to the stationary box. The at least one moveable wing includes at least one of a door hinged to the stationary box or a drawer mounted via slide actuators to the stationary box. The cabinet also includes a reed switch attached to the stationary box, a magnet attached to the at least one moveable wing, and at least one light emitting diode (LED) fixture installed within the stationary box. Opening the at least one wing separates the reed switch from the magnet and permits current to flow to the at least one LED fixture to illuminate at least an interior portion of the stationary box.

Disclosed herein are various embodiments related generally to computer vision, graphics, image scanning, and image processing as well as associated mechanical, electrical and electronic hardware, computer software and systems, and wired and wireless network communications to form at least three-dimensional models or images of objects and environments.

A modular vapor-tight light fixture is provided herein which generally includes first and second vapor-tight light modules, and a coupling for connecting the first and second vapor-tight light modules. Each of the vapor-tight light modules includes: a channel housing; a lens secured to the channel housing; a plurality of solid state light generating elements; and, first and second end caps. Each of the channel housings includes first and second rails which each define a mounting channel. The coupling includes mounting strip portions configured such that, with the first and second vapor-tight light modules being adjacent, the mounting strip portions are simultaneously received in the mounting channels of both the first and second vapor-tight light modules. Advantageously, with the subject invention, fully enclosed vapor-tight light modules may be provided at shorter lengths which are connected by the coupling to provide a fixture comparable in length to prior-art vapor-tight light fixtures.

A lighting arrangement with an exchangeable lighting cap, includes a holder for the lighting cap and a lock lever to lock the lighting cap in position on the holder. The front face of the lighting caps has at least one light emitting element, for emitting light in a direction perpendicular to the front face. The edge of the front face has two positioning slots that are perpendicular to the direction of illumination. The holder comprises an opening for receiving the front face and has two positioning elements arranged at a rim of the opening, wherein the positioning elements can be inserted into the positioning slots of the lighting cap by elastic deformation to fix the position of the lighting cap on the holder. The lock lever has an open position for inserting the lighting cap into the holder and a locked position for locking the lighting cap in position.

The present invention relates to an illumination device, including: a support member; and at least one first light source on the support member and at least one second light source on the support member, where the first light source has a first light distribution, the second light source has a second light distribution, and the first light distribution is different from the second light distribution.

A luminaire (61) is disclosed with a close coupled ballast (62) having a support arm (66) from which is suspended or hung a reflector, and preferably a variable focus reflector (41), having either a single ended lamp (3) or double ended lamp (23). The luminaire (61) is supported from a greenhouse rafter (9) by filaments (10, 11) which are connected one to the ballast (62) and the other to the free end of the support arm (66). In one embodiment the arm (66) is connected to a rigid side plate (64) which is mounted on the ballast (62). In another embodiment the arm (66) is connected to a side plate (164) which is hinged. The arrangement enables flimsy reflectors (41) to be close coupled with electronic ballasts in a way which minimises Radio Frequency Interference (RFI).

Systems, devices, and methods for a tailgate LED (light emitting diode) cap system, device and method, for attaching LED caps on top of truck tailgates as a safe and secure after-market or retrofit product. The LED cap can be easily attached to the tops of truck tailgates with fasteners but are not removable without unlocking locks covering the fasteners.