A module comprising an electronic component and an electrical connector that are interconnected by a printed circuit board that is fastened to a heat sink, the connector includes a housing, connection contacts and a bundle of wires, which are secured to the housing and respectively interconnected electrically. The housing is arranged on one side of the board such that the contacts pass through the board so as to emerge onto the other side and to be connected electrically there. The board is fastened to the heat sink by the side thereof bearing the contacts. The surface of the heat sink receives the board having a boss at least level with the contacts, so as to avoid electrical contact between the contacts and the heat sink.

A lighting module is shown and described having a housing with an opening therethrough. A forward portion of the opening may be enclosed by a cap and a rearward portion of the opening may be enclosed by a transparent media. A second media may extend from the opening through a wall of the housing. The cap may be securable to a bar via a mounting apparatus. A PCBA with one or more operational groups of LEDs may be secured within the opening, such that light may be emitted through the media. A second PCBA with one or more operational groups of LEDs may be secured within the opening, such that light may be emitted through the second media. Each operational group may be integrated with a control system of a vehicle, and may be operated individually or collectively. Each operational group may correspond to similar or different colors of light.

A vehicle tailight includes a housing seat and a light cover cooperatively defining an accommodation space, and a main light emitting device disposed in the accommodation space and including first and second light emitting members capable of emitting first and second color lights, respectively, a reflective plate, an isolation portion corresponding to the second light emitting members, and a light transmitting plate having a light guide portion for transmitting a portion of the first color light rearwardly to the light cover and to guide the other portion thereof to reflect forwardly onto the reflective plate, which in turn, reflects the first color light rearwardly. A light adjusting structure guides the second color light to project rearwardly.

A vehicle lamp unit includes a plurality of light emitting units, each light emitting unit including a semiconductor light emitting element, a circuit substrate on which the semiconductor light emitting element is mounted and having a circuit for supplying power to the semiconductor light emitting element, and an optical member for reflecting or refracting light emitted from the semiconductor light emitting element, and a coupling mechanism which couples the plurality of light emitting units. The plurality of light emitting units are arranged such that the circuit substrates are separated from each other and partially overlap with each other in a vehicle width direction. A number of the plurality of light emitting units is three or more.

A rear liftgate assembly with at least one rear lamp applique assembly and process for manufacturing same. The lamp applique assembly includes a rear lamp applique housing with at least one attachment surface for attaching to an outer panel of the liftgate assembly. A plurality of integrated snap attachment features are provided to connect the lamp applique assembly to the outer panel, thereby eliminating additional bonding and fasteners. A self-sealing wire harness connected accepts an integrated lamp connector, thereby eliminating the need for access openings, to further minimize water intrusion, and eliminate gaskets.

A vehicle lamp includes: a first light guide including a first light guiding portion having a first light emitting surface and a first light incident surface; a second light guide including a second light guiding portion having a second light emitting surface and a second light incident surface; and a first reflector configured to reflect a part of light emitted from the first light emitting surface. The first light guiding portion and the second light guiding portion are disposed on opposite sides across the first reflector, the first light guiding portion is positioned on a light emitting direction side of the second light guiding portion, and a part of the second light guiding portion is positioned outside the first light guiding portion in the light guide direction.

The invention refers to a lighting device (18) comprising a light-emitting module (2) and an optical system. The optical system comprises a first reference face (16), wherein the first reference face (16) is configured to accommodate the light-emitting module (2); and at least one spring element (20) is provided for fixing the light-emitting module (2) to the optical system in a clamping position, wherein the at least one spring element (20) comprises a first spring section (26) configured to exert a spring force in a first spatial direction (f.sub.1) towards the first reference face (16) in the clamping position, wherein the at least one spring element further comprises a second spring section (28) configured to exert a spring force towards a second spatial direction (f.sub.2) in the clamping position, and wherein the second spatial direction (f.sub.2) is different from the first spatial direction (f.sub.1). The invention further relates to a method for fixing a light-emitting module (2) to an optical system.

The invention refers to a lighting device (18) comprising a light-emitting module (2) and an optical system. The optical system comprises a first reference face (16), wherein the first reference face (16) is configured to accommodate the light-emitting module (2); and at least one spring element (20) is provided for fixing the light-emitting module (2) to the optical system in a clamping position, wherein the at least one spring element (20) comprises a first spring section (26) configured to exert a spring force in a first spatial direction (f.sub.1) towards the first reference face (16) in the clamping position, wherein the at least one spring element further comprises a second spring section (28) configured to exert a spring force towards a second spatial direction (f.sub.2) in the clamping position, and wherein the second spatial direction (f.sub.2) is different from the first spatial direction (f.sub.1). The invention further relates to a method for fixing a light-emitting module (2) to an optical system.

The present invention relates to a rear lamp which has a 3D light distribution effect so as to represent a sense of depth by the infinity mirror effect and, more specifically, to a rear lamp configured to produce a movable light distribution image.

The present invention relates to a rear lamp which has a 3D light distribution effect so as to represent a sense of depth by the infinity mirror effect and, more specifically, to a rear lamp configured to produce a movable light distribution image.