The invention provides a lighting device (100) comprising a vapor chamber unit (200), a heat sink (300), and a plurality of light sources (10), wherein: the vapor chamber unit (200) comprises a vapor chamber (210) defined by at least a first plate (211) and a second plate (212) having an average plate distance (d1), wherein the vapor chamber (210) comprises a first A chamber end (221) and a second chamber end (222) defining a chamber length (L1), wherein the vapor chamber unit (200) comprises (i) a first external face (231) defined by at least part of the first plate (211), wherein the first external face (231) is convex, and (ii) a second external face (232) defined by at least part of the second plate (212); the heat sink (300) is thermally coupled to the vapor chamber unit (200); and the light sources (10) are configured to generate light source light.

The invention provides a lighting device (100) comprising a vapor chamber unit (200), a heat sink (300), and a plurality of light sources (10), wherein: the vapor chamber unit (200) comprises a vapor chamber (210) defined by at least a first plate (211) and a second plate (212) having an average plate distance (d1), wherein the vapor chamber (210) comprises a first A chamber end (221) and a second chamber end (222) defining a chamber length (L1), wherein the vapor chamber unit (200) comprises (i) a first external face (231) defined by at least part of the first plate (211), wherein the first external face (231) is convex, and (ii) a second external face (232) defined by at least part of the second plate (212); the heat sink (300) is thermally coupled to the vapor chamber unit (200); and the light sources (10) are configured to generate light source light.

The present disclosure discloses a heat dissipating structure for automotive LED headlight, which comprises a radiator formed integrally, wherein the radiator comprises one or more heat radiating arms. The heat radiating arm is provided with an embedded groove used for accommodating an assembly of a lamp bead board and a heat pipe. The beneficial effect of the present disclosure is that: the heat of the lamp bead board is transferred to the radiator, thus the heat dissipation efficiency has been greatly improved.

The present disclosure discloses a heat dissipating structure for automotive LED headlight, which comprises a radiator formed integrally, wherein the radiator comprises one or more heat radiating arms. The heat radiating arm is provided with an embedded groove used for accommodating an assembly of a lamp bead board and a heat pipe. The beneficial effect of the present disclosure is that: the heat of the lamp bead board is transferred to the radiator, thus the heat dissipation efficiency has been greatly improved.

An electronic device includes a back frame, a first heat source, a second heat source, a guiding member and a fan. The first heat source is disposed on a first side of the back frame. The second heat source is disposed on a second side of the back frame. The guiding member is disposed on the second side of the back frame. The fan is disposed corresponding to the guiding member. At least part of an airflow path is formed between the first heat source and the second heat source.

A lighting device is provided and includes: a lamp main housing including a containing cavity, wherein a recess in communication with the containing cavity and a snap-fit structure configured to connect an optical accessory are disposed at an end of the lamp main housing, and a position of the recess corresponds to a position of the snap-fit structure; a heat dissipation device disposed in the containing cavity; a light source in heat-conduction connection with the heat dissipation device, and located inside of the containing cavity or the recess; a front-end housing including a throughout hollow cavity, wherein an end of the front-end housing is disposed on the light source, and another end of the front-end housing faces an outer side of the recess and passes through the recess; wherein light emitted by the light source passes through the hollow cavity of the front-end housing and is emitted outward.

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.

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.

According to one aspect, a luminaire comprises a luminaire housing, at least one LED disposed within the luminaire housing, and an LED driver circuit disposed within a driver housing. The driver housing comprises an inner portion and an outer portion, wherein at least a part of the inner portion is disposed between the LED driver circuit and the outer portion and wherein the LED driver circuit is in thermal communication with the outer portion.

The present invention provides a lamp capable of preventing an increase in weight and dissipating heat of the LED module. The lamp of the present invention includes an LED module serving as a light source, a heat transfer unit, a light distribution unit, a casing including an opening, and a light transmissive cover. The LED module includes plural LEDs and an LED substrate having an LED-mounting surface on which the plural LEDs are mounted. The light distribution unit is disposed on a light emitting side of the LED module. The LED module and the light distribution unit are disposed in the casing. The light transmissive cover is disposed over the opening of the casing. The LED module is disposed in the casing to be distanced from the casing. The heat transfer unit is disposed such that heat of the LED module can be dissipated into the casing.