An emitter and a method for emitting light are described. The emitter has a substrate with a substrate surface and at least one LED element arranged on the substrate surface for generating the light to be emitted. An active cooling unit for cooling the at least one LED element has at least one cooling channel. The at least one cooling channel is arranged on the substrate surface in a beam path of at least one portion of the light to be emitted, which can be generated by means of the at least one LED element, for redirecting the light to be emitted.

An optical module includes a light plate and a heat dissipation structure. The heat dissipation structure includes a first substrate connected to the light plate, and a second substrate disposed under the first substrate. The first and second substrates are made of aluminum or an aluminum alloy material. A first anodized aluminum layer is disposed on a side of the first substrate adjacent to the second substrate. A second anodized aluminum layer is disposed on a side of the second substrate adjacent to the first substrate. A gap is defined between the first and second anodized aluminum layers, and there are disposed cooling droplets in the gap. When each light-emitting element is at a first heating value, the respective cooling droplet moves to a position under the light-emitting element. When each light-emitting element is at a second heating value, the respective coolant drop leaves from under the light-emitting element.

A technique for more appropriately adjusting a temperature of an electronic apparatus is provided. Temperatures of a panel substrate are detected in a plurality of measurement regions set in the panel substrate, and temperatures in a plurality of adjustment regions set in the panel substrate are individually adjusted in accordance with the temperatures of the panel substrate detected in the plurality of measurement regions.

A display module is provided and includes: a backplane, defining a receiving slot; a light source assembly, arranged at a bottom of the receiving slot; an optical substrate, snapped to an upper portion of the accommodation slot, wherein a sealing cavity is defined between the optical substrate and the optical source assembly; a coolant, received in the sealing cavity; and a self-sealing fixation assembly, rotatably arranged on a slot wall of the receiving slot. In a first state, the optical substrate abuts against the self-sealing fixation assembly in a direction towards the bottom of the receiving slot; and, in a second state, the self-sealing fixation assembly is in an interference fit with the optical substrate, the self-sealing fixation assembly and the optical substrate are locked with each other to cooperatively define the sealing cavity.

Embodiments of the invention include a light emitting diode (LED) including a semiconductor structure. The semiconductor structure includes an active layer disposed between an n-type region and a p-type region. The active layer emits UV radiation. The LED is disposed on the mount. The mount is disposed on a conductive slug. A support surrounds the conductive slug. The support includes electrically conductive contact pads disposed on a bottom surface, and a thermally conductive pad disposed beneath the conductive slug, wherein the thermally conductive pad is not electrically connected to the LED.

In one embodiment, the disclosure relates to a system of stacked and connected layers of circuits that includes at least one pair of adjacent layers having very few physical (electrical) connections. The system includes multiple logical connections. The logical interconnections may be made with light transmission. A majority of physical connections may provide power. The physical interconnections may be sparse, periodic and regular. The exemplary system may include physical space (or gap) between the a pair of adjacent layers having few physical connections. The space may be generally set by the sizes of the connections. A constant flow of coolant (gaseous or liquid) may be maintained between the adjacent pair of layers in the space.

A light source cooling body (100), a light source assembly, a luminaire and a method to manufacture a light source cooling body or a light source assembly are provided. The light source cooling body comprises a homogeneous body (104) made of a thermally conductive material. The homogenous body comprises an open space that comprises a wick structure, a condenser (112) and an evaporator (116). Near the evaporator the light source cooling body has an interface area (102) to thermally couple with a light source and to receive heat from the light source. The condenser is arranged away from the interface area. A portion 114 of the open space is tubular shaped. The open space may hold a cooling liquid partially in the gaseous phase and partially in the liquid phase and the wick structure is configured to transport the cooling material in the liquid phase towards the evaporator.

The light irradiating device includes a substrate; a plurality of light emitting diode elements disposed on a surface of the substrate; a cooling unit which is disposed on a rear surface of the substrate; an inner wall which is disposed to enclose a light passage area through which light of the plurality of light emitting diode elements passes; a housing which accommodates the substrate, the plurality of light emitting diode elements, the cooling unit, and the inner wall and generates a space between the inner wall and the housing; an air inlet which introduces air in the light passage area onto the rear surface of the substrate; a flow channel which passes through the rear surface of the substrate and connects the air inlet and the space; and a circulation port which is provided to discharge the air in the space to the light passage area.

The present disclosure further contemplates a system and method that cools metal core printed circuit boards by circulating a liquid coolant so that it contacts the base metal of the metal core printed circuit board. In one example the present disclosure contemplates a direct liquid cooled MCPCB system that may include a liquid cavity creating component coupled to the base plate of a MCPCB allowing a liquid coolant to come into contact with the base plate of the MCPCB for cooling of the MCPCB. The direct liquid cooled MCPCB system may minimize thermal bottlenecks between the electrical components and the cooling fluid while reducing the number of components required in previous liquid cooled electronics systems.

Disclosed is a heat-dissipation device of an LED. The device comprises one or a plurality of heat conducting material silks; a heat-dissipation housing of an LED chip is contacted with one end of the heat conducting material silks through heat conducting materials or in a direct manner, in order to transmit the heat to the heat conducting material silks and heat the surrounding air through the heat conducting material silks; the heat conducting material silks are arranged in an air flowing pipeline, and the heat is taken away by the flowing air; the pipeline is made of insulation materials. The weight and size of the heat-dissipation device of the LED can be reduced exponentially under the condition that a proper working temperature for the LED chip is ensured, and the ground insulation of the whole heat-dissipation device can be ensured.