An IMS printed circuit board comprises a card edge connector with a first face and a second face, the second face being in electric contact with the metallic core and the card edge connector comprising a plurality of signal traces. At least one of the signal traces is a ground trace which is in electrical connection with a ground connection of the printed circuit board and is intended to be connected to a ground pin comprised in a card edge connector socket. The IMS printed circuit board also provides a card edge connector socket with a plurality of pins, one of the pins being a ground pin and being configured to receive the ground trace of the printed circuit board. An electronic assembly comprises the printed circuit board and the card edge connector socket and a lighting device are also provided.

An LED simulated flame device includes a semi-transparent diffusion cover in a candle flame shape, a light-emitting lamp plate, and a control circuit module. The light-emitting lamp plate includes a PCB substrate, and several LED chips shading between brightness and darkness at random, and the LED chips include an up-lighting LED chip that is located on a top edge of the PCB substrate, emits light upward, and is configured to project light and shadows onto a middle upper portion of the diffusion cover, two mid-lighting LED chips that emit light toward a front surface of the diffusion cover, are configured to project light and shadows onto a middle portion of the diffusion cover, and are located on front and back surfaces of the PCB substrate, and a down-lighting LED chip that corresponds to a bottom portion of the diffusion cover, emits light upward, and is configured to supplement light.

The present disclosure relates to an LED vehicle lamp with a frustum base plate. The LED vehicle lamp includes a base plate, a circuit board and a plurality of LED chips. The base plate is a frustum base plate. The frustum base plate is arranged on an axis of the LED vehicle lamp. A width of an upper bottom surface of the frustum base plate is smaller than that of a lower bottom surface of the frustum base plate. An axis of the circuit board is parallel to an axis of the frustum base plate. A width of the circuit board is smaller than that of the upper bottom surface of the frustum base plate. The circuit board is installed on the upper bottom surface of the frustum base plate, and the plurality of LED chips are installed on the circuit board.

The present invention relates to an LED filament (100) comprising a carrier (110) comprising a plurality of LEDs (140) arranged in at least two columns of LEDs (150, 160). The plurality of LEDs (140) are grouped into at least two different subsets of LEDs (120, 130), wherein a first subset of the LEDs (120) is configured to emit light of a first color temperature, CT1, and a second subset of the LEDs (130) is configured to emit light of a second color temperature, CT2, CT2 being different from CT1. The LEDs (140) of the at least two different subsets of LEDs (120, 130) are arranged in an alternating intersecting configuration in the at least two columns of LEDs (150, 160) such that each column (150) comprises alternating segments (132, 124) configured to emit light of the first and the second color temperatures, respectively.

There is provided a photocatalytic reactor arranged to receive one or more airborne contaminants. The photocatalytic reactor includes a photo-catalyst for photocatalytic degradation of one or more of the contaminants disposed on a substrate, and a light-emitting diode circuit board comprising a circuit board with one or more first light-emitting diodes mounted to a first side of the circuit board and one or more second light-emitting diodes mounted to a second side of the circuit board. The substrate is arranged to be illuminated by both the one or more first light-emitting diodes and the one or more second light-emitting diodes in order to facilitate photocatalytic degradation.

Accroding to the present disclosure, a heat sink, which may be used e.g. for LED lamps or bulbs for motor vehicle lights, includes: a plate-like portion extending along an axis with opposed mounting surfaces for at least one heat source, such as e.g. a LED lighting source, and a finned portion thermally coupled with the plate-like portion and including a plurality of annular fins extending around said axis.

The current invention applying super slim LED-unit(s) has built-in contactors has (a) magnetic only or (b) conductive magnetic-movable-kits so can attach or detachable metal magnetic-field reactive buss-strips. The conductive-movable type which also can deliver electric current from buss-strips of track light. The super slim LED light or units is a DC powered LED light has optics design become super thin and none bright-spots. The said LED-units install under the light-block material housing or parts, and light-beam go through at least of reflective surface at inner surface or walls. The said LED-unit install on hard or bendable circuit board with divider the compartment only has LED, lit-lens, reflective housing. The compartment is only space where light-beam traveling and has multiple times reflected and emit out from top lens. The said light beam emit out from LED-unit(s) reflected by high reflective surface or wall including (1) white high-polished plastic or (2) metalized mirror-like or (3) shining metal piece back-and-forth and light emit out from top lens. The current invention has multiple time reflective and refractive optic theory to make the super thin light for SMD LED(s) on hard or bendable PCB to get in-direct light beam. To get none bright-sports by not install LED(s) under face top lens. The Track LED light or LED-unit has slim features with different size can use as ceiling, closet, kitchen, laundry, door, garage, patio or anywhere for building, residence, house for indoor or outdoor use.

Apparatus and method provide underwater lighting to illuminate a site within a body of water in which underwater lighting apparatus is immersed during a lighting cycle. A housing is constructed of a heat-conductive material and LED arrays are affixed to the housing, within a sealed chamber, to conduct heat from the LED arrays to the housing such that heat generated by the LED arrays during the lighting cycle will be conducted directly to the housing and dissipated by the housing to the surrounding body of water. Light provided by the LED arrays is passed through corresponding lens members located for directing light in different directions. At the same time, fouling by marine organisms is resisted.

A light wall for cultivating at least one plant indoors may be provided. The light wall may include a first side, a second side, a top side, a bottom side, a front side, and a back side. The light wall may further include a first lighting structure unit disposed within sides of the light wall, and may include a first set of mechanical devices configured to enable movement of the light wall. The first lighting structure may be configured to provide light to the at least one plant through at least the first side. The first set of mechanical devices may be configured to enable movement at least along an axis substantially perpendicular to the first side.

Lighting devices that comprise a light source and a reflector, the reflector comprising first, second and third reflector regions. In some devices, a first portion of light is reflected by the first region and then by the third reflector region, a second portion of light is reflected by the second region and forms a primary beam, and at least 5% of the first portion of light that is reflected by the third region is within the primary beam of light. In some devices, at least 5% of all light reflected by the first reflector region travels from the first reflector region directly to the third reflector region. In some devices, at least 5% of all light reflected by the third reflector region traveled directly from the first reflector region to the third reflector region. In some devices, the reflector comprises means for providing the features described above.