A locking channel has a series of inwardly extending locking tab members. The base section of a neon lamp is positioned within the locking channel and secured and locked in place by means of the locking tab members. This system can be used with locking channels which are straight, angled or of any curved configuration.

A sliding lamp includes a base having an electric conductive unit, a driving mechanism disposed on the base, and a slider having a light source and a light emitting area for emitting light out. The slider is disposed on the base in a way that the driving mechanism is capable of driving the slider to slide between a closed position and a wide-open position. When the slider is at the closed position, the light emitting area is completely covered and the light source is electrically disconnected from the electric conductive unit. In the process that the slider slides from the closed position to the wide-open position, the light source is electrically connected with the electric conductive unit and the light emitting area is gradually exposed. Therefore, the sliding lamp is turned on/off or adjusted in brightness by sliding and thereby changed in shape thereof at the same time.

An LED filament and an LED light bulb applying the same are provided. The LED filament includes a conductive section including a conductor; two or more LED sections connected to each other by the conductive section, and each of the LED sections includes two or more LED chips electrically connected to each other through a wire; two electrodes, electrically connected to the LED section; and a light conversion layer with a top layer and a base layer, covering the LED sections, the conductive section and the two electrodes, and a part of each of the two electrodes is exposed respectively. The LED filament is supplied with electric power no more than 8 W, when the LED filament is lit, at least 4 lm of white light is emitted per millimeter of filament length.

Provided is a printed circuit board (PCB) assembly that includes a plurality of printed circuit boards to be electrically connected together, and each being formed of a first shape and having a plurality of lighting elements arranged thereon to form of a second shape creating a lighting pattern of a desired shape with the plurality of lighting elements, when electrically connected together. The first shape of the printed circuit boards being different from the second shape of the arrangement of the lighting elements.

Embodiments of the present disclosure provide a method and apparatus for illuminating. An exemplary apparatus includes a substrate having a longitudinal axis, and a first plurality of spaced apart fingers extending perpendicular to the longitudinal axis from a first side of the substrate. The apparatus further includes second plurality of spaced apart fingers extending perpendicular to the longitudinal axis of a second side of the substrate, wherein the first side of the substrate is opposite the second side of the substrate. The apparatus still further includes a first plurality of spaced apart lighting elements located on a third side of the substrate, wherein the first plurality of spaced apart lighting elements are spaced along the longitudinal axis of the substrate, and a second plurality of spaced apart lighting elements located on a fourth side of the substrate.

A light bulb apparatus includes a light bulb shell, a bulb head, and a heat sink cup. The heat sink cup has a first end connected to the light bulb shell, and a second end connected to the bulb head. The light bulb apparatus includes a flexible filament and a central support. The flexible filament has a first terminal and a second terminal, and the central support provides a first electrode electrically connected to the first terminal, and provides a second electrode for electrically connected to the second terminal. The light bulb apparatus includes an expanding structure and a driver module. The expanding structure is mechanically coupled to the central support, and includes a plurality of holding portions for holding the flexible filament. The driver module is electrically connected to the bulb head and the central support for providing electrical power to the flexible filament.

A lighting assembly comprising a housing (2), a lighting system and a reflector system. The housing (2) has a longitudinal direction, a lateral direction and a height direction which are perpendicular to each other. The lighting system is installed in the housing (2) and configured to produce light and emit the light out from the housing (2), the lighting system comprising a first light source (61). The reflector system is configured for reflecting the light produced by the lighting system out from the housing (2) and comprises a first reflector (41) including a first reflector surface (411) which is a concave surface with a first radius of curvature (r1). The first reflector (41) is also provided with a second reflector surface (412) which is a concave surface with a second radius of curvature (r2) which is larger than the first radius of curvature (r1), a centre of curvature (cc2) of the second reflector surface (412) being spaced from a centre of curvature (cc1) of the first reflector surface (411). The lighting assembly is configured to be such that most of the light emitted by the lighting system out from the housing (2) passes via the reflector system.

Side light LED troffer tube. In an aspect, a side light LED tube is provided that includes a tube having at least one light receiving portion configured to receive light and gradient optics formed on the tube. The gradient optics providing a transparency gradient configured to distribute the light to achieve a selected emitted light intensity variation across a selected surface of the tube.

A vehicle light assembly comprising: a flexible lighting strip with a multitude of light-emitting diodes that are bent around at least two linear independent axes; an optically passive lighting strip terminator that is coupled to an end surface of the flexible lighting strip and is arranged such that light emitted by the light emitting diodes is at least partly recycled; a light guiding structure comprising a light receiving surface that receives light emitted by the flexible lighting strip and the lighting strip terminator and surface defines a bending of the flexible lighting strip and a primary light emission surface that emits at least a part of the light received via the light receiving surface; a coupling structure that mechanically couples the flexible lighting strip and the lighting strip terminator to the light receiving surface. The vehicle light assembly can further be comprised in a front or rear vehicle light.

Disclosed is a helmet provided with a radar reflector. The helmet includes a helmet body formed in a shape corresponding to a shape of a user head, and the radar reflector mounted on an outer surface of the helmet body to reflect a radar signal transmitted from radar equipment. The radar reflector includes a plurality of reflection units each concaved in a trigonal pyramid shape having one opened surface, each of the plurality of reflection units reflecting the radar signal. Thus, by applying the radar reflector to the helmet of a user aboard an object to be detected by using a radar signal, the radar signal is effectively reflected in bad weather or at night, thereby improving the recognition rate of radar equipment.