A runway-embedded flash lighting device, including: a body; a ceiling member; a light guide member; and an LED flash light source, wherein the body is configured to be embedded in a runway, the ceiling member is disposed in an upper opening of the body and configured to be exposed to a runway surface when the body is embedded in the runway, the ceiling member includes a flash emission window, the light guide member is disposed in the flash emission window, the LED flash light source is disposed inside the body and configured to emit a flash toward the light guide member, and the light guide member is configured to allow the flash emitted from the LED flash light source to be emitted from the flash emission window to outside the runway-embedded flash lighting device.

An LED luminaire including an outer LED support member having a plurality of LED arrays positioned on a lower side thereof, an LED driver housing centrally located within an interior of the outer LED support member, wherein the outer LED support member is secured to the LED driver housing with a plurality of attachment arms that extend from inner surface of the outer LED support member to the LED driver housing, such that are open spaces between the plurality of attachment arms and between the inner surface of outer LED support member and the LED driver housing, and a plurality of heat dissipating fins positioned on an upper surface of the outer LED support member extending towards the LED driver housing.

Provided is a light source device in which the housing is not full of heat, and the risk of inhaling dust in the housing or the risk of reduction of life of the fan device becomes reduced. In an aspect, a light source device according to the present disclosure includes a light source; a light source control unit for controlling turning on/off and a quantity of light of the light source; a cooling fan for cooling the light source; and a fan control unit for controlling a number of revolutions of the cooling fan, wherein the fan control unit is configured to: control the number of revolutions of the cooling fan to become a first number of revolutions depending on the quantity of light of the light source when the light source is turned on, and control the number of revolutions of the cooling fan to become a second number of revolutions lower than the first number of revolutions by waiting for a predetermined waiting time when the light source is turned off.

Provided is a light source device in which the housing is not full of heat, and the risk of inhaling dust in the housing or the risk of reduction of life of the fan device becomes reduced. In an aspect, a light source device according to the present disclosure includes a light source; a light source control unit for controlling turning on/off and a quantity of light of the light source; a cooling fan for cooling the light source; and a fan control unit for controlling a number of revolutions of the cooling fan, wherein the fan control unit is configured to: control the number of revolutions of the cooling fan to become a first number of revolutions depending on the quantity of light of the light source when the light source is turned on, and control the number of revolutions of the cooling fan to become a second number of revolutions lower than the first number of revolutions by waiting for a predetermined waiting time when the light source is turned off.

An omnidirectional light-emitting bulb shell and a light bulb having the same, comprising a light-transmitting bulb shell, wherein, the light-transmitting bulb shell forms an enclosed space, at least one heat dissipation channel is arranged through the light-transmitting bulb shell, two ends of the heat dissipation channel are communicated with outside of the bulb shell respectively, and at least one LED filament is arranged in the enclosed space on the surface of at least part of the heat dissipation channels that is within the enclosed space. The bulb shell and the light bulb having the same can implements 360 degree omnidirectional illumination with large light-emitting angle and high light-emitting efficiency, and have good heat dissipation performance, thereby increasing the service life of the LED lamp.

An omnidirectional light-emitting bulb shell and a light bulb having the same, comprising a light-transmitting bulb shell, wherein, the light-transmitting bulb shell forms an enclosed space, at least one heat dissipation channel is arranged through the light-transmitting bulb shell, two ends of the heat dissipation channel are communicated with outside of the bulb shell respectively, and at least one LED filament is arranged in the enclosed space on the surface of at least part of the heat dissipation channels that is within the enclosed space. The bulb shell and the light bulb having the same can implements 360 degree omnidirectional illumination with large light-emitting angle and high light-emitting efficiency, and have good heat dissipation performance, thereby increasing the service life of the LED lamp.

A two-part device, automotive lighting unit and method of manufacture are described herein. A two-part device includes an assembly. The assembly includes a first part having a first fixation face and a second part separate from the first part. The second part has a second fixation face. The first and second parts are arranged adjacent one another with the first fixation face in contact with the second fixation face. The assembly further includes a circlip fixation position that has a rounded shape transverse to the fixation face. The two-part device also includes a circlip, which engages the rounded shape at the circlip fixation position, fixing the first and second parts together.

A cooling system for a light emitting diode (“LED”) assembly includes a fluid configured to absorb heat at the LED assembly, a heat exchanger coupled to one or more substrates of the LED assembly, where the heat exchanger is configured to exchange heat between the LED assembly and the fluid, and a pump configured to circulate the fluid along the LED assembly and the heat exchanger, where the fluid exhibits a turbulent flow at the LED assembly, the heat exchanger, or both, while circulated by the pump.

A cooling system for a light emitting diode (“LED”) assembly includes a fluid configured to absorb heat at the LED assembly, a heat exchanger coupled to one or more substrates of the LED assembly, where the heat exchanger is configured to exchange heat between the LED assembly and the fluid, and a pump configured to circulate the fluid along the LED assembly and the heat exchanger, where the fluid exhibits a turbulent flow at the LED assembly, the heat exchanger, or both, while circulated by the pump.

An LED light fixture for a hazardous location includes an axially elongated enclosure fabricated from a glassfiber reinforced plastic material, at least one axially elongated linear light emitting diode (LED) module mounted in the enclosure, and an LED driver module mounted in the housing that operates the at least one linear light emitting diode. The LED driver module and the at least one axially elongated linear LED module are operable within a target peak temperature limit for the hazardous location, without utilizing heat sinks to dissipate heat in order to provide acceptable thermal management.