A wall mounted light fixture includes a body at least partially defining a housing. The body has a first side facing an interior of the housing and a second side facing the exterior of the housing. The first side of the body has a plurality of front connecting features and the second side of the body has a plurality of rear connecting features. A light emitter is positioned in the interior of the housing and supported by the first side of the body. A lens is connected to at least one of the front connecting features. A mounting component is connected to at least one of the rear connecting features.

A wall mounted light fixture includes a body at least partially defining a housing. The body has a first side facing an interior of the housing and a second side facing the exterior of the housing. The first side of the body has a plurality of front connecting features and the second side of the body has a plurality of rear connecting features. A light emitter is positioned in the interior of the housing and supported by the first side of the body. A lens is connected to at least one of the front connecting features. A mounting component is connected to at least one of the rear connecting features.

A luminaire comprising a base, a circuitry housing attached to the base and comprising circuitry, a first rotational structure attached to the circuitry housing, a second rotational structure attached to the first rotational structure, and a lighting apparatus attached to the second rotational structure. The circuitry is positioned in electrical communication with each of the base and the lighting apparatus. The first rotational structure is attached to the circuitry housing so as to rotate about a first rotational axis that is parallel to a longitudinal axis of the luminaire. The second rotational structure is attached to the first rotational structure so as to rotate about a second rotational axis that is parallel to a transverse axis of the luminaire.

Lighting fixtures are provided. In one example implementation, a lighting fixture can include a housing, one or more drivers, and means for securing the one or more drivers to the housing to decrease thermal resistance between one or more of the drivers and the housing. The lighting fixture can also include an LED system comprising a light engine having a plurality of LED devices. The plurality of LED devices can be arranged on an LED board of the light engine such that a first portion of the LED board has a first density of LED devices and a second portion of the LED board has a second density of LED devices. The first density can be different than the second density.

Lighting fixtures are provided. In one example implementation, a lighting fixture can include a housing, one or more drivers, and means for securing the one or more drivers to the housing to decrease thermal resistance between one or more of the drivers and the housing. The lighting fixture can also include an LED system comprising a light engine having a plurality of LED devices. The plurality of LED devices can be arranged on an LED board of the light engine such that a first portion of the LED board has a first density of LED devices and a second portion of the LED board has a second density of LED devices. The first density can be different than the second density.

Lighting fixtures are provided. In one example implementation, the lighting fixture can include a housing portion and one or more modular lighting components mechanically coupled to the housing portion. Each modular lighting component can include a lighting assembly (e.g., an LED lighting assembly) and a heat sink portion. The one or more modular lighting components can be selectively removable from the housing portion to configure the lighting fixture for a plurality of different lighting configurations.

Lighting fixtures are provided. In one example implementation, the lighting fixture can include a housing portion and one or more modular lighting components mechanically coupled to the housing portion. Each modular lighting component can include a lighting assembly (e.g., an LED lighting assembly) and a heat sink portion. The one or more modular lighting components can be selectively removable from the housing portion to configure the lighting fixture for a plurality of different lighting configurations.

This invention disclosed a lamp tube comprising a tube body, a light emitting member, and a support member. The support member has a support portion and an expansion portion. The support portion is located inside the tube body; the light emitting member is located on the support portion of the support member; the expansion portion of the support member extends from one side of the support portion of the support member, with the light emitting member installed to the inner wall of the tube body. At least part of the light from the light emitting member is emitted outside the tube body along the expansion portion. A lamp tube according to embodiments of the present invention is inexpensive, has a simple manufacturing process, and the light source can be emitted in a smaller angle, improving the concentration of light.

The present invention provides a positioning device for an optical membrane that includes at least one positioning hole formed on the optical membrane and at least one positioning pole interposed into the positioning hole respectively, the optical membrane is fixed onto a carrying substrate by traversing said positioning holes by said positioning poles, wherein the profile of each positioning hole extending in corresponding position in the expansion and shrink direction of the optical membrane. A certain width could be reserved in the positioning hole to allow the optical membrane expand and shrink freely at each fixing point and the positioning pole cannot interfere with the positioning hole at the moment of the optical membrane expands and shrinks to cause bending, thus to guarantee flatness of the optical membranes and improve the quality of the backlight module.

A light-emitting device including a substrate with a top surface and a bottom surface opposite to the top surface and a plurality of LED chips disposed on the top surface and configured to generate a top light visible above the top surface and a bottom light visible beneath the bottom surface, each LED chip comprising a plurality of light-emitting surfaces. The substrate has a thickness greater than 200 μm and comprises aluminum oxide, sapphire, glass, plastic, or rubber. The plurality of LED chips has an incident light with a wavelength of 420-470 nm. The top light and the bottom light have a color temperature difference of not greater than 1500K.