A lighting device system includes a lighting device module having a module housing configured to be selectively inserted through an opening in a panel or a base. Driver electronics are configured to be electrically coupled to the lighting device module. A heat sink member is located adjacent the opening in the panel or the base. A movable biasing device has a first position to apply a bias force on the module housing, pressing the module housing toward the heat sink member to increase thermal transfer. The moveable biasing device has a second position to provide improved access to the driver electronics through the opening in the panel or base relative to the first position. The movable biasing device is selectively moveable from the first position to the second position, or from the second position to the first position.

An embodiment of the present application provides a lighting lamp comprising: a first housing, extending in a first direction and provided with a first fixing part, wherein, the first fixing part extends along the first direction; a second housing, provided at an end of the first housing along the first direction, wherein, the second housing is provided with a second fixing part, and the second fixing part extends along a thickness direction of the second housing; and at least one connecting component, comprising at least one first connecting part provided in close to the first housing and at least one second connecting part provided in close to the second housing, wherein, the at least one first connecting part and the first fixing part are fixedly connected, and the at least one second connecting part and the second fixing part are fixedly connected.

An embodiment of the present application provides a lighting lamp comprising: a first housing, extending in a first direction and provided with a first fixing part, wherein, the first fixing part extends along the first direction; a second housing, provided at an end of the first housing along the first direction, wherein, the second housing is provided with a second fixing part, and the second fixing part extends along a thickness direction of the second housing; and at least one connecting component, comprising at least one first connecting part provided in close to the first housing and at least one second connecting part provided in close to the second housing, wherein, the at least one first connecting part and the first fixing part are fixedly connected, and the at least one second connecting part and the second fixing part are fixedly connected.

Disclosed are a heat dissipation device (140) and a lighting device (10). The heat dissipation device (140) comprises a substrate (141), a plurality of fins (1431) and at least one airflow generating device (145), wherein the plurality of fins (1431) are arranged on the substrate (141) at certain intervals and are connected to the substrate (141); and the at least one airflow generating device (145) is arranged at the ends of the plurality of fins (1431) away from the substrate (141), and an airflow generated by the airflow generating device (145) flows through at least some gaps of the plurality of fins (1431) in the direction of the substrate (141) and is jointly guided by the substrate (141) and the plurality of fins (1431) to be diffused. The plurality of fins (1431) are arranged on the substrate (141), such that heat absorbed by the substrate (141) is rapidly transferred to the plurality of fins (1431), and the fins (1431) and the substrate (141) are cooled by the airflow generating device (145), thereby effectively improving the heat dissipation efficiency of the heat dissipation device; and when the heat dissipation device (140) is used in the lighting device (10), the heat dissipation device (140) can rapidly dissipate heat of a light source (130), and therefore, the lighting device (10) can work stably for a long time.

Disclosed are a heat dissipation device (140) and a lighting device (10). The heat dissipation device (140) comprises a substrate (141), a plurality of fins (1431) and at least one airflow generating device (145), wherein the plurality of fins (1431) are arranged on the substrate (141) at certain intervals and are connected to the substrate (141); and the at least one airflow generating device (145) is arranged at the ends of the plurality of fins (1431) away from the substrate (141), and an airflow generated by the airflow generating device (145) flows through at least some gaps of the plurality of fins (1431) in the direction of the substrate (141) and is jointly guided by the substrate (141) and the plurality of fins (1431) to be diffused. The plurality of fins (1431) are arranged on the substrate (141), such that heat absorbed by the substrate (141) is rapidly transferred to the plurality of fins (1431), and the fins (1431) and the substrate (141) are cooled by the airflow generating device (145), thereby effectively improving the heat dissipation efficiency of the heat dissipation device; and when the heat dissipation device (140) is used in the lighting device (10), the heat dissipation device (140) can rapidly dissipate heat of a light source (130), and therefore, the lighting device (10) can work stably for a long time.

Improvements a portable elevated lighting system that uses LED lighting elements for illumination. The LED lights are selected based upon the light transmission angle so the fewest number of lighting elements are needed to provide an even flood or focus of light from the system. A reflector works as a heat sink to remove heat from the LED lights and extend the operation life of the LED's. Thermal paste and or a thermal pad is used between the LED lighting element and the frame to conduct sufficient heat away from the LED element. Two versions are shown as a stadium light and as a circular flood light that provides lighting without shadows or bright areas. The system can be operated from a generator or solar for charging batteries so the lighting can operate self-contained without producing noise.

A projection type image display apparatus including a light source apparatus includes a light emitting element emitting blue light; a phosphor receiving the blue light to emit predetermined light; a heat sink provided with a bottom portion and a plurality of heat radiation fins extending from the bottom portion; and a cooling fan arranged to cool the plurality of heat radiation fins of the heat sink. The light emitting element is attached to the bottom portion of the heat sink. The phosphor is attached to the bottom portion of the heat sink at a predetermined interval from the light emitting element. Heat pipes conducting heat by repeating evaporation and liquefaction of working liquid are embedded in the bottom portion. The heat pipes are respectively provided with sections opposing the light emitting element in a thickness direction of the bottom portion.

The purpose of the present invention is to realize a lighting device of thin, low power consumption and small light distribution angle. The present invention takes the following structure to realize the above task: A lighting device having an emitting surface and a bottom opposing to the emitting surface including: a resin, set between the emitting surface and the bottom, having a hole at a center, a reflection block set in the hole at a side of the emitting surface, an LED, which is a light source, set in the hole at a side of the bottom, a space between the LED and the reflection block, in which the resin is contained in a container whose inner surface is a reflecting surface.

A lighting device system includes at least one lighting device module having a module housing configured to be inserted at least partially through an opening in a panel, and at least one heat sink member having a contact surface. The at least one heat sink member is located adjacent the opening in the panel. The module housing is held in contact with the contact surface of the at least one heat sink member when the module housing is inserted at least partially through the opening in the panel in an installed state. The module housing is configured to be selectively withdrawn from the contact surface of the heat sink member, through the opening in the panel.

An elongated lighting module having an asymmetric illumination source formed from at least two rows of light emitting diodes (LEDs) that extend along the long axis of the module and are independently controllable. The lighting modules are powered via a wiring harness that extends down a support pole to a power converter stack having LED drivers to control the modules. The power supply for lighting module includes a power enclosure having individual light emitting drivers for powering the rows of light emitting diodes that can adjust the power level to compensate for the loss of power from another of the light emitting drivers. The power supply may also include a backup that can be switched over to power the rows of light emitting diodes in the event of a failure.