In a door mirror device for a vehicle, a projector protrudes out toward a lower side from a circuit board, and the projector projects a pattern onto a ground surface. Moreover, illuminating LEDs and guide bodies are fixed to a lower surface of the circuit board. Due to the illuminating LEDs generating lights and the guide bodies guiding these lights, the guide bodies irradiate the lights from lower ends, and the ground surface is illuminated. Here, the lower ends of the guide bodies are disposed further toward a lower side than the projector. Therefore, shadows, which are due to the projector, arising in lights that illuminate the ground surface can be suppressed.

A present invention is a vehicle lamp provided with: an elongated light guide member provided in a lamp chamber, an incident end part being positioned below said member; and a light source provided in the lamp chamber so as to face the incident end part. The light guide member has: a light guide main part having an elongated shape in which one end is the incident end part, a prism part being provided along the longitudinal direction, the prism part causing a portion of the light incident from the incident end part to be emitted in the irradiation direction; and a flange part projecting from the light guide main part in the direction intersecting the irradiation direction. The flange part is provided with a reflecting surface that forms a depression angle with a projecting end face when viewed from the incident end part side within a prescribed range viewed in the longitudinal direction.

A lighting system for a motor vehicle includes a printed circuit board equipped with light emitting diodes for emitting light beams in lighting directions and an optical module formed to propagate and transmit the light beams. The optical module has a reception surface to receive the light beams and an emission surface for retransmitting the light beams. The lighting system also includes at least one element for masking the light beams emitted by the light emitting diodes. The element for masking which extends from at least one of the light emitting diodes toward the reception surface and substantially parallel to the lighting direction of the at least one light emitting diode, over at least a part of the periphery of the at least one light emitting diode and over at least a part of a distance separating the at least one light emitting diode and the reception surface.

The present application discloses a light pipe assembly having a light pipe with a proximal end, an opposing distal end, a length between the proximal end and the distal end, and a surface, the surface having an emitting portion and an overlay portion, where the light pipe is a material capable of transmitting light with a first refractive index; and a reflective secondary surface having a second refractive index and a width, the reflective secondary surface positioned adjacent the overlay portion of the light pipe, where the first refractive index is greater than the refractive index of air, and the second refractive index is greater than the first refractive index. In at least one embodiment, the reflective secondary surface is a non-metallic material capable of reflecting light. In at least one embodiment, the width of the reflective secondary surface varies along the length of the light pipe.

A lighting module disclosed in an embodiment comprises: a plurality of light emitting devices on a substrate; and a reflector arranged in the direction of emission of light from each light emitting device on the substrate. The light emitting device has a light exit surface, and the reflector has a reflecting surface concave toward the substrate, at least a portion of the reflecting surface corresponding to the light exit surface of the light emitting device. The reflecting surface is arranged at a height that increases gradually in proportion to the interval from the light emitting device arranged in the light incident direction. The reflecting surface comprises a plurality of convex portions arranged in a first direction and first bridge portions that connect between the plurality of convex portions. The first bridge portions are arranged along the convex portions and are arranged to be lower than a straight line that connect high points of adjacent convex portions. The convex portions and the first bridge portions have the same length in a second direction, which is perpendicular to the first direction, and the area of the convex portions may be larger than the area of the first bridge portions.

A lighting module disclosed in an embodiment comprises: a plurality of light emitting devices on a substrate; and a reflector arranged in the direction of emission of light from each light emitting device on the substrate. The light emitting device has a light exit surface, and the reflector has a reflecting surface concave toward the substrate, at least a portion of the reflecting surface corresponding to the light exit surface of the light emitting device. The reflecting surface is arranged at a height that increases gradually in proportion to the interval from the light emitting device arranged in the light incident direction. The reflecting surface comprises a plurality of convex portions arranged in a first direction and first bridge portions that connect between the plurality of convex portions. The first bridge portions are arranged along the convex portions and are arranged to be lower than a straight line that connect high points of adjacent convex portions. The convex portions and the first bridge portions have the same length in a second direction, which is perpendicular to the first direction, and the area of the convex portions may be larger than the area of the first bridge portions.

A radar reflective vehicle breakdown warning sign comprises primarily a body and a projecting lamp, and a remote control for connecting to the body and the projecting lamp. In an interior of the body is disposed a control circuit and a transmission component connected to the control circuit. The transmission component is pivotally connected to a vehicle breakdown warning sign. On the vehicle breakdown warning sign are disposed radar wave reflecting patches which may reflect the radar waves emitted by a vehicle with an autonomous driving function. In an interior of the projecting lamp is disposed a control circuit and a light emitting component connected to the control circuit.

A radar reflective vehicle breakdown warning sign comprises primarily a body and a projecting lamp, and a remote control for connecting to the body and the projecting lamp. In an interior of the body is disposed a control circuit and a transmission component connected to the control circuit. The transmission component is pivotally connected to a vehicle breakdown warning sign. On the vehicle breakdown warning sign are disposed radar wave reflecting patches which may reflect the radar waves emitted by a vehicle with an autonomous driving function. In an interior of the projecting lamp is disposed a control circuit and a light emitting component connected to the control circuit.

A vehicle lamp includes a light emitting source, a support substrate configured to support the light emitting source, a heat sink configured to support the support substrate and dissipate heat from the light emitting source, and a light controller configured to control light from the light emitting source. The heat sink includes an opening configured to measure the radiant heat of the support substrate.

A light module for a motor vehicle comprises at least one light source capable of emitting light rays, a support bearing the source, an electrical power supply cable of the source, an optical deflection element arranged so as to deflect the light rays emitted by this source to form a projected light beam at the output of the light module, and a guiding device for guiding the optical deflection element in rotation about an axis of rotation, in order to transversely shift the projected light beam. According to the invention, the support comprises a first part, bearing the light source, and the second part, between which there is inserted at least a part of the guiding device, and the cable passes through the rotation guiding device to be connected to said light source.