The present disclosure relates to vehicle lighting devices, and discloses a headlight optical element. The headlight optical element includes a light incident portion, a light transmitting portion and a light emergent portion which are connected in sequence, wherein the light incident portion includes a plurality of light incident surfaces connected sequentially in a left-right direction; the light incident surfaces are curved surfaces protruding backwards in the optical axis direction; and light emergent surfaces are curved surfaces protruding forwards in the optical axis direction. In addition, the present disclosure further discloses a headlight module, a vehicle headlight and a vehicle. The headlight optical element provided by the present disclosure is small in size, high in optical precision, accurate in light pattern, convenient to mount and low in cost.

A substrate support body includes a support plate, an enclosure member, and a bonding material. The enclosure member is arranged on the support plate. The bonding material is arranged on an entire surface of an inner region of the enclosure member and is bonded to the support plate.

A vehicle lamp includes a substrate, a lens having a pivotal attachment to the substrate and defining a lamp chamber between the lens and the substrate, at least one light source provided in the lamp chamber, an alignment portion integral with and extending from the lens parallel to the substrate and having an aperture, and an adjustment mechanism extending through the aperture and the substrate, the adjustment mechanism configured to adjust alignment of the lens with a single-point adjustment.

An automotive solid-state headlamp includes a lamp body extending in a longitudinal direction, the lamp body having a rear base portion and a front portion and including a support member and a light-transmissive housing, a plurality of solid-state light sources arranged on the support member at the rear base portion of the lamp body, a drive circuitry electrically coupled to the light sources and arranged at the rear base portion of the lamp body and configured to operate the plurality of light sources when energized and reflector optics arranged at the front portion, wherein the solid-state light sources are configured to emit light towards the reflector optics, the reflector optics including a first reflector optic portion and a second reflector optic portion and wherein each of a plurality of first reflective surfaces disposed on the first reflector optic portion extend in an annular region around the longitudinal direction from the plurality of solid-state light sources towards the first reflector optic portion.

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.

Disclosed in an embodiment are a semiconductor device and a head lamp comprising the same, the semiconductor device comprising: a substrate; a plurality of semiconductor structures arranged at a center part of the substrate; first and second pads arranged at an edge part of the substrate; a first wiring line electrically connecting at least one of the plurality of semiconductor structures to the first pad; a second wiring line electrically connecting at least one of the plurality of semiconductor structures to the second pad; and a wavelength conversion layer arranged on the plurality of semiconductor structures, wherein the plurality of semiconductor structures is arranged to be spaced apart from each other in a first direction and a second direction, the first direction and the second direction cross each other, the interval distance between the plurality of semiconductor structures is 5 μm to 40 μm and the thickness of the wavelength conversion layer is 1 μm to 50 μm.

A light source module including a ceramic substrate, copper traces, light emitting units, and heat conductive columns is provided. The first heat conductive column and the second heat conductive column correspond to the first light emitting unit and the second light emitting unit respectively. The negative electrode of the first light emitting unit is connected to the first copper trace, the positive electrode of the second light emitting unit is connected to the second copper trace, and the positive electrode of the first light emitting unit and the negative electrode of the second light emitting unit are connected to the third copper trace. An end of the first heat conductive column is connected to the positive electrode of the first light emitting unit, and an end of the second heat conductive column is connected to the negative electrode of the second light emitting unit.

In an embodiment an automotive solid-state headlamp includes a lamp body extending in a longitudinal direction, the lamp body having a rear base portion and a front portion and including a support member disposed in a light-transmissive housing, a plurality of solid-state light sources arranged on the support member at the rear base portion of the lamp body, and a drive circuitry electrically coupled to the light sources and arranged at the rear base portion of the lamp body and configured to operate the plurality of light sources when energized, wherein the plurality of light sources, when energized, are configured to cause the solid-state lamp to emit, through the light-transmissive housing (a) a luminous flux of at least 1500 lumens +/−10% when energized with a 13.2 Volt test voltage, or of at least 1750 lumens +/−10% when energized with a 28 Volt test voltage, or (b) a luminous flux of at least 1350 lumens +/−10% when energized with a 13.2 Volt test voltage, or of at least 1600 lumens +/−10% when energized with a 28 Volt test voltage.

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.

A vehicle lamp module, a vehicle lamp and a vehicle. The vehicle lamp module comprises a circuit board, at least one reflector and light shields in one-to-one correspondence with the reflectors. Each of the light shields comprises a plurality of light shield positioning plugs, and the circuit board comprises light shield positioning sockets corresponding to the light shield positioning plugs, thereby realizing direct positioning of the light shields and the circuit board. The light shields and the reflector are respectively and directly positioned with the circuit board, such that accurate and good positioning among vehicle lamp optical element systems consisting of the circuit board, the light shields and the reflectors is realized, and position errors caused by indirect positioning among optical elements due to the fact that a radiator is used as a positioning piece are avoided, ensuring light form effect, and improving the module performance.