A light source (14) is configured to emit light for lighting a predetermined area. A LiDAR sensor (15) is configured to sense information of an outside of a vehicle. A first screw mechanism (16) is configured to adjust posture of the light source (14). A second screw mechanism (17) is configured to adjust posture of the LiDAR sensor (15). Adjustment by one of the first screw mechanism (16) and the second screw mechanism (17) is performed on the basis of adjustment that has been performed by the other one of the first screw mechanism (16) and the second screw mechanism (17).

A motor-vehicle lighting device including a plurality of primary optical elements, intermediate lenses, and a curved projecting lens. Each primary optical element has a curved exit refracting surface and comprises a plurality of rectangular light guides that are each intended to interact with one light-emitting diode one laser. Each intermediate lens is placed between an exit refracting surface of the primary optical element and the projecting lens. Each intermediate lens is configured to distribute and concentrate the radiation issued from an exit refracting surface of the element over and onto the projecting lens. The lighting device is configured so as to project the diode radiation entering into the light guides and exiting via the projecting lens in the form of luminous pixels, or luminous strips, the light intensity of each of which is controlled despite the curvature of the projecting lens.

A motor-vehicle lighting device including a plurality of primary optical elements, intermediate lenses, and a curved projecting lens. Each primary optical element has a curved exit refracting surface and comprises a plurality of rectangular light guides that are each intended to interact with one light-emitting diode one laser. Each intermediate lens is placed between an exit refracting surface of the primary optical element and the projecting lens. Each intermediate lens is configured to distribute and concentrate the radiation issued from an exit refracting surface of the element over and onto the projecting lens. The lighting device is configured so as to project the diode radiation entering into the light guides and exiting via the projecting lens in the form of luminous pixels, or luminous strips, the light intensity of each of which is controlled despite the curvature of the projecting lens.

An industrial vehicle includes a vehicle body, a pair of right and left front pillars provided in the front portion of the vehicle body, and a headlight provided on the front pillar. The headlight is provided with a light and a bracket to which the light is attached. The bracket has an attachment plate and a protective frame formed in the front portion of the attachment plate. The protective frame has a vertical frame and a first horizontal frame and a second horizontal frame shorter than the vertical frame.

An industrial vehicle includes a vehicle body, a pair of right and left front pillars provided in the front portion of the vehicle body, and a headlight provided on the front pillar. The headlight is provided with a light and a bracket to which the light is attached. The bracket has an attachment plate and a protective frame formed in the front portion of the attachment plate. The protective frame has a vertical frame and a first horizontal frame and a second horizontal frame shorter than the vertical frame.

A system is provided that allows a driver to customize one or more vehicle components such as lights. The system may allow the user to specify how each light behaves in response to certain conditions or triggers. The customizations may include displaying predetermined or customized shapes and colors, and may include customizing the timing and brightness of the lights. To ensure that the customizations comply with one or more laws, the system may determine the current location of the vehicle. The system may use the location of the vehicle to determine what rules, regulations, and laws apply to the vehicle. The system may then determine if the customizations comply with the determined rules, regulations, and laws. If the customizations comply, the system may allow the vehicle component to operate according to the customizations. If the customizations do not comply, the driver may be alerted and/or the customizations may be adjusted to comply.

The present disclosure described herein, in general, relates to a system 500 for controlling headlamps of a vehicle. The system 500 may comprise a signal processing unit 509, a relay circuit 401, a switch 302 and a user device 407. The user device 407 comprises a GPS tracker 408-A, an output unit 409, a processor 408-B and a memory 408-C. The system comprises comparing one or more parameters with the predefined threshold value, notifying information based upon the one or more parameters, instructing the user to change the status of the headlamp using the switch 302 based upon the comparison of the one or more parameters with the predefined threshold value and controlling the status of the headlamps upon receiving command by the user based upon the instructions or automatically operating the relay circuit 401 based upon the received signals.

The present disclosure described herein, in general, relates to a system 500 for controlling headlamps of a vehicle. The system 500 may comprise a signal processing unit 509, a relay circuit 401, a switch 302 and a user device 407. The user device 407 comprises a GPS tracker 408-A, an output unit 409, a processor 408-B and a memory 408-C. The system comprises comparing one or more parameters with the predefined threshold value, notifying information based upon the one or more parameters, instructing the user to change the status of the headlamp using the switch 302 based upon the comparison of the one or more parameters with the predefined threshold value and controlling the status of the headlamps upon receiving command by the user based upon the instructions or automatically operating the relay circuit 401 based upon the received signals.

A downlight fixture includes: a light source board arranged to emit optical light; an electrical connector electrically connected with the light source board for providing power to the light source board; a metallic cup shaped heat sink attached with the light source board; a plastic housing attached with the metallic cup shaped heat sink; and a heat sink, attached with the plastic housing. The metallic cup shaped heat sink, the plastic housing, and the heat sink are arranged to dissipate heat generated by the light source board.

An imaging device includes an LED element mounted on a surface of an LED substrate and electrically connected to a wiring pattern. For the surface of the LED substrate, a heatsink for dissipating heat of the LED substrate is arranged to face the surface of the LED substrate on which surface the LED element is mounted. The heatsink includes: a base portion attached in a manner allowing heat transfer in which a heat transfer surface of the base portion faces the surface of the LED substrate, the base portion allowing the illumination light from the LED element to pass through the base portion; and fins integrally protruding from the heat dissipating surface, being arranged spaced from each other, and being cooled by air that is naturally convected.