A modular light housing apparatus for removably holding a light assembly includes a light transmissible portion and a cover portion. The cover portion is releasably coupled to the light transmissible portion and the light transmissible portion has a mounting region and a light compartment configured for transmitting light from the apparatus. Wire passages are provided between the mounting region and the light compartment, which is defined by a frame. The frame has a plurality of wire conduits, each near one of the wire passages. The wire conduits each have a conduit opening opposite one of the wire passages. The cover portion has a light mount for holding the light source, and the wires travel through the wire passages, wire conduits, and conduit openings to engage a light source.

A modular LED lamp structure comprising a LED light source of the type mounted on a plate, a heat sink element having a flat face for supporting the LED light source and a central axis perpendicular to the flat face, a mask for locking the light source designed to press the light source itself, keeping it pressed against the flat supporting face of the sink element, means for removably fastening the metal mask to the sink element.

A polymer luminaire including a polymer housing having a longitudinal axis. An electrical board is mounted to an inner surface of the housing. The electrical board has an outer surface defining a plane extending at an angle to horizontal when the longitudinal axis of the housing is oriented parallel to horizontal. A light source is mounted to the electrical board and electrically connected to the electrical board for emitting light from the housing.

A dynamic light source for a display is disclosed. The dynamic light source comprises a first light source located inside a first device; and a second light source. The first device is configured to allow light from the first light source to exit the first device in a first cone of angles and to reflect light incident outside the cone of angles back towards the first light source. The first device is configured such that injected light from the second light source is reflected by the first light source in a second cone of angles substantially coincident with the first cone of angles and that light output by the first device from the second light source is attenuated more than light output by the first light source, and an amount of attenuation is based on an intended dynamic power range of the dynamic light source.

The purpose is to realize a lighting device which can project a light spot of rectangle with a simple structure. The invention is: A lighting device having a light source unit 1, the light source unit 1 including a funnel shaped reflector 10 and an LED 20, in which the funnel shaped reflector 10 includes a neck and an opening, the LED 20 is disposed at the neck of the funnel shaped reflector 10, a plan view of the opening is a rectangle, and provided a distance from the neck to the opening along axis is d, and one side of the rectangle is x, either one of the first light source unit and the second light source unit satisfies, d / x is 2 or larger.

The purpose is to realize a lighting device of thin, small light distribution angle and high intensity illumination. The invention is: a lighting device, which emits light in a direction perpendicular to a normal surface, including: light source units, disposed radially with a certain azimuth with respect to a center of the lighting device, each of the light source units, having an optical axis parallel to the major surface, and emitting light toward the center of the lighting device, each of the light source units including a funnel shaped reflector, which has an opening and a neck, and an LED light source disposed at the neck, mirrors disposed opposing to the openings of the light source units, in which the mirrors reflect light emitted from the light source units to the direction perpendicular to the major surface.

Disclosed is a luminaire such as an LED downlight which is suitable for mounting in ceiling cavities of commercial environments. An example luminaire (200) comprises a light source (202) including an integral primary optic which is configured to transmit light toward a second optic (214). The second optic (214) is a lens configured to receive light from the light source (202) via the primary optic and transmit at least part of the received light toward a circular reflector (201). The circular reflector (201) is configured to direct light received from the second optic (214) away from the luminaire (204). A shape of the second optic (214) is interdependent with a shape of the circular reflector (201), and the shape of the second optic (214) and circular reflector (201) act in combination to transmit light away from the luminaire with a non-circular illuminance distribution (206).

The present utility model discloses a three-dimensional reflective finish structure, a plurality of three-dimensional reflective units are integrally formed on the surface of a substrate, and at least one three-dimensional reflective surface is provided on a partial surface or the entire surface of the substrate, among which, a three-dimensional reflective surface comprises a plurality of three-dimensional reflective units scattered on the surface of the substrate or continuously distributed on the surface of the substrate and connected into one piece; and a three-dimensional reflective unit comprises at least one three-dimensional polyhedral reflective pit in the shape of a polygonal cone sinking below the surface of the substrate. The present utility model is less prone to abrasion and has extremely strong abrasion resistance as the three-dimensional reflective unit relatively sinks below the surface of the substrate material; has better light gathering and reflection effects, as well as better visual effects as the three-dimensional reflective unit has a plurality of reflective surfaces arranged obliquely to the surface of the substrate; and has simple structure and low cost.

A digitally controlled LED illuminator sheet that produces far-field illumination patterns or light field distributions that increase light utilization and application efficiency. A dynamic directional LEDs (or other kinds of solid-state light sources) sheet is positioned under each lenslet of a microlens array. Individual LED beam pointing direction depends on off-axis position relative to optical axis of lenslet. Individual beams from independent LEDs form illumination pixels at the illumination plane or within a volume space and can be modulated in intensity. Illumination pixels partially overlap in far-field illumination plane and illumination volume. Over a large illumination space many illumination pixels will partially superimposed on neighboring illumination pixels, with the overlap being in increments smaller than the size of a pixel. The LEDs can be digitally turned on or off and/or pulse width or amplitude modulated to produce far-field illumination patterns or light field distributions with spectral efficiency and efficacious intensity.

An integrated-lighting-module may have a driver cap, a heat sink module, a LED light chip, an optical reflector, and a holder/trim. The driver cap may be configured to hold a driver within the driver cap to power the LED light chip. The driver cap may attach to a top of the heat sink module. The heat sink module may be finned at various locations. The holder may attach to the heat sink module with the optical reflector and the LED light chip disposed between elements of the holder and elements of the heat sink module. Trim, such as MR16 sized trim, a lamp, and/or a lens holder, may attach to bottom flanges of the holder. The integrated-lighting-module may be adjusted without interfering with the trim. The holder may be trim in some embodiments.