The disclosure generally relates to generating lighting in an efficient way while in the outdoors. The designs are meant to maximize the amount of light generated, by the smallest assembly that is rugged to use in general outdoor activities and water sports. Further designs are related to hands-free mounting capabilities on outdoor equipment such as bikes, surfboards, snowboards and other similar equipment. Additional features include various filters, waterproofing, recharging or lighting differences which provide greater visual or photographic advantages to the user.

Example embodiments relate to luminaire head assemblies with brackets. One example luminaire head assembly includes a housing provided with a socket assembly. The luminaire head assembly also includes a light source arranged in the housing. Additionally, the luminaire head assembly includes a bracket releasably attached to the housing. The bracket is configured to fix the housing to a pole. The bracket has a first end for connection to a pole or pole connector and a second end attached to the housing. The bracket is provided with a through-hole at the second end. The socket assembly extends at least partially in the through-hole.

An LED lamp includes a heat sink including a first surface with a first receiving portion thereof, and at least one LED plate installed at a bottom portion of the first receiving portion; a second receiving portion arranged on a top portion of the first receiving portion to receive a transparent element therein that covers a light-emitting surface of the LED plate; an insertion port arranged on the second receiving portion and located on a first plane of a first end of the heat sink; a first moving member arranged on the first plane of the first end and corresponding to the insertion port, a second moving member arranged on a second plane of the first end and movably connected to the heat sink, both the first and second moving members movably connected to each other and moving relative to the heat sink to open or close the insertion port.

A display apparatus is provided that includes: a printed circuit board (PCB); a light emitting diode (LED) chip mounted on the PCB and configured to emit light; an optical dome disposed over and enclosing the LED chip; a distributed Bragg reflector (DBR) layer arranged on an upper surface of the LED chip; a liquid crystal panel configured to block or pass light output from the LED chip; and an optical film arranged between the LED chip and the liquid crystal panel. A ratio of a height of the optical dome to a diameter of a bottom surface of the optical dome is 0.25 to 0.31, and the optical film includes a quantum dot sheet formed to enhance color reproducibility by making a change in wavelength of light.

Embodiments disclosed herein include to interconnectable circuit boards that can be constructed into three-dimensional shapes for use as lighting sources. An interconnectable circuit board array is included having a plurality of circuit board assemblies. The circuit board assemblies can include a first longitudinal edge, and a second longitudinal edge, and a plurality of bendable lateral board to board connectors. The plurality of bendable lateral board to board connectors are configured to provide electrical communication between a first circuit board from amongst the plurality of circuit board assemblies and a second circuit board from amongst the plurality of circuit board assemblies. Longitudinal edges of the first circuit board and of the second circuit board define a gap between the first circuit board and the second circuit board. The gap being bridged by at least one of the lateral board to board connectors. Other embodiments are also included herein.

In a bending system and a method for using the same, the bending system includes a bending robot provided between a press brake and a predetermined setting area that is arranged in front of the press brake to assist in bending a workpiece. The bending robot includes a robot hand for holding the workpiece on a pallet that is set in the predetermined setting area. An image pickup unit, which picks up an image of the workpiece on the pallet from an oblique upper direction, is provided above and anterior to the predetermined setting area. A first illumination unit, which illuminates an image pickup area of the image pickup unit, is erected on a left front side of the predetermined setting area. A second illumination stand, which illuminates the image pickup area of the image pickup unit, is erected on a right front side of the predetermined setting area.

The present invention relates to a method for joining at least two flexible foils (10a-b). The method comprises the steps of (i) providing a first flexible foil (10a) having a first row (12) of light emitting diodes (14) and a first set of electrically conductive tracks (16) for supplying current to the first row (12) of light emitting diodes (14), (ii) providing a second flexible foil (10b) having a pot second row (12) of light emitting diodes (14) and a second set of electrically conductive tracks (16) for supplying current to the second row (12) of light emitting diodes (14), and (iii) joining the first flexible foil (10a) and the second flexible foil (10b) at an overlap (22) of the first flexible foil (10a) and the second flexible foil (10b), wherein a metal strip or wire (24; 24) gets embedded between the first flexible foil (10a) and the second flexible foil (10b) at the overlap, and wherein the metal strip or wire (24; 24) electrically connects to the first and second sets of electrically conductive tracks (16).

A light emitting device includes a substrate, a plurality of light emitting diodes, a window, and a reflector. The substrate has a first region and a second region. The plurality of light emitting diodes are disposed on the first region of the substrate. The window has a dome shape and is disposed to cover the first region. The window is configured to control a traveling path of light emitted from the plurality of light emitting diodes. The reflector is configured to support the window and reflect the light emitted from the plurality of light emitting diodes. The reflector has an opening that exposes the plurality of light emitting diodes disposed on the substrate. A distance between two adjacent light emitting diodes of the plurality of light emitting diodes can be 500 micrometers or less.

A backlight module and a display panel are disclosed. The backlight module includes an assembled light plate composed of multiple light plates assembled together. There is a gap between every two adjacent light plates. The backlight module further includes a light supplementation structure covering the gap and having a fixed end fixedly connected with one of the two adjacent light plates, and a free end located on the other one of the two adjacent light plates. The light supplementation structure is provided at the corresponding position of the gap to supplement light to the gap of the assembled light plate, and the light supplementation structure is only fixedly connected with one of the light plates on both sides of the gap, and is not connected with the other light plate.

A floodlight, comprising a lamp board, a lens, a radiator and a frame; wherein the lamp board has a light emitting side and a backlight side, and at least one mounting hole is provided on the lamp board; the lens is arranged on the light emitting side, and the lens has a near light side portion close to the lamp board, and at least one first connector is provided on the near light side portion corresponding to a position where the at least one mounting hole is provided; the radiator is arranged on the backlight side, and at least one second connector are arranged on the radiator corresponding to the position where the at least one mounting hole is provided; and one of the first connectors and the at least one second connector can pass through the at least one mounting hole and be detachably connected with the other.