The present application relates to a vehicle LED lamp, and particularly to the technical field of lighting lamps. The vehicle LED lamp includes a terminal, a driver module and a LED light-emitting board which are connected in turn. The LED light-emitting board is cylindrical, one end of the driver module is embedded into the LED light-emitting board, and the other end is embedded into the terminal. The terminal is sleeved on one end of the LED light-emitting board and connected to a vehicle power supply in forward or reverse connection. The present applicant can realize the split assembly of the vehicle lamp.

An LED bulb structure includes a heat dissipation base, a power connector, a light-emitting module, an insulation cover, and a light-guiding cover. The power connector is disposed on a bottom side of the heat dissipation base. The light-emitting module includes a circuit substrate disposed on a top side of the heat dissipation base and a plurality of LED chips electrically connected to the circuit substrate. The LED chips are surroundingly disposed on the circuit substrate and adjacent to an outer perimeter surface of the circuit substrate. The insulation cover is disposed on the circuit substrate, and the insulation cover has a surrounding main portion and a convex portion disposed on a top side of the surrounding main portion. The light-guiding cover is disposed on the insulation cover. The light-guiding cover has a through opening formed on a top side thereof for exposing the convex portion.

The present disclosure provides a light-emitting diode (LED) lighting device. The LED lighting device includes a lamp base, a glass shell, a heat-dissipating cup, a driving power source, an LED light source module, and an optical portion. The LED light source module, the heat-dissipating cup, and the driving power source are arranged from top to bottom inside the glass shell. A top portion of the glass shell is connected to the optical portion and a bottom portion of the glass shell is connected to the lamp base. The heat-dissipating cup faces upwardly and an outer sidewall of the heat-dissipating cup forms a close contact with an inner sidewall of the glass shell. The LED light source module is fixed within the heat-dissipating cup. The driving power source is positioned under the heat-dissipating cup and a space is formed between the driving power source and the heat-dissipating cup.

A luminaire comprising a heat spreader and a heat sink disposed around and thermally communicates with the heat spreader. The heat sink forms a trim plate configured to be disposed completely external of a can light fixture or an electrical junction box. The luminaire also includes an optic securely retained relative to one of the heat spreader and the heat sink on one side of a plane defined by a lower surface of the trim plate and extends to the other side of the plane defined by the lower surface of the trim plate, as well as a light source disposed on the heat spreader and comprising a plurality of light-emitting diodes (LEDs). The plurality of LEDs are positioned entirely on one side of the plane defined by the lower surface of the trim plate. The light source is in thermal communication with the heat spreader.

There is disclosed a forward cooling headlight comprising a body, a lens coupled to the body and a heatsink coupled to the body. There is also a heatpipe and at least one light. The light is coupled to the heatsink, wherein the heatpipe is coupled to the heatsink at a first end, and to the body at a second end. The heatsink draws heat away from the light, via the heatpipe and towards the body. There can be at least one synthetic jet coupled to the heatpipe to aid in cooling the light. In addition, in at least one embodiment, there can be at least two lights with at least two different drivers with a first driver driving a first light and a second driver driving a second light wherein when each of the lights is lit it is capable of generating a different focal point.

An encapsulated LED switch that incorporates a MOSFET power drivers, high current transistors, or other suitable power drivers in a PCB that attaches to the LED switch such that a low power LED switch controls the output of a high-power driver. The selected power driver PCB can be adapted to different load requirements by making simple changes. The PCB's can be interchanged to provide for a predetermined output power required for a particular application. In addition, the wire gauge size of the wires attached to the MOSFET power driver PCB can also be varied to match intended load requirements. For applications in which the LED switch is used in hostile environments, such as marine applications, the LED switch and its associated power driver PCB are encapsulated to protect the circuitry from environmental factors such as high humidity, salt water, etc.

A mount system comprising a mount receiver, a light, and a mount attachment. The light includes a body, a head pivotably coupled relative to the body by a hinge, and a light emitting element mounted on the head. The mount attachment is configured to engage both the mount receiver and the light to secure the light to the mount receiver.

A lighting device contains a first circuit board and a second circuit board. The first circuit board has one or more connecting sections having overall at least two contact areas. The second circuit board has an opening through which the connecting section of the first circuit board can extend. At least two contact elements, which are electrically connected to conductive tracks of the second circuit board, are arranged on the second circuit board. Each contact element has a contact region by which the contact element butts against one of the contact areas of the first circuit board. As a result, an electrical connection is produced between the two circuit boards.

A lighting device includes a carrier having at least one section that has a triangular cross section. The carrier includes at least one mounting portion on an edge of the triangular cross section, and a heat sink body portion adjacent to, and protruding sidewards from, the at least one mounting portion. At least one structure is mounted to the at least one mounting portion. The at least one structure includes at least one mounting face having an arrangement direction. The at least one lighting module is mounted along the arrangement direction on the at least one mounting face. The at least one light guide is optically coupled to the at least one lighting module.

An overhead light fixture includes a driver assembly and a light-emitting assembly. The driver assembly includes a driver and a housing. The light-emitting assembly is operably connected to the driver and configured for downward emission of light from a light source of the light-emitting assembly. The light-emitting assembly is detachably secured to the driver assembly. The light fixture is configured to be mounted to a canopy sheet of an overhead canopy, with the driver assembly disposed above the canopy sheet and the light-emitting assembly disposed below the canopy sheet. The driver assembly is optionally configured so that, when the light-emitting assembly is detached from the driver assembly, the driver is removable downwardly through the base portion. A bezel is optionally disposed around a lens of the light-emitting assembly, for aesthetic reasons and/or for controlling a degree of lateral emission of light from the light fixture.