A light-irradiating device of the disclosure comprises: a light-irradiating unit comprising a housing in which a light-emitting element is disposed, the housing comprising a light irradiation surface through which light from the light-emitting element can be transmitted; and a gas supply unit comprising a flow channel connected to a part of the light irradiation surface of the housing. A printing device of the disclosure comprises: the light-irradiating device mentioned above; a conveying unit which conveys a medium to be printed while causing the medium to face the light irradiation surface of the light-irradiating device; and a printing unit which is disposed adjacent to and upstream from the light-irradiating device in a conveyance direction of the medium to be printed.

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 LED device includes a multi-sided heat spreader element with a longitudinal multi-sided wall at least partly enclosing an internal space, with a plurality of LEDs mounted to the outer surface the heat spreader element, and a flow space for a cooling medium in the internal space. The tubular heat spreader element has at least one layer of a thermally conductive metal which is bendable from a flat shape to the multi-sided shape. The multi-sided shape may be tubular with a smoothly curved or multi-faceted polygonal wall. The wall of the LED device may incorporate two-phase cooling elements such as vapor chambers to maintain the LEDs at a constant temperature, and may include a temperature-controlled fan unit to control the LED temperature, and also control the wavelength and frequency of light emitted by the LEDs. A method for manufacturing the LED device is also disclosed.

A light emitting device to be mounted on a mount surface of a vehicular compartment includes a housing including a first section having an air intake hole and a second section having an air discharge hole, a cooling fan device arranged in the first section, and a light emitter arranged in the second section. The housing further includes a discharge cavity having the discharge hole. The light emitter and the cooling fan device are arranged in a first arrangement direction laterally along the mount surface. The light emitter includes a board member and a light emitting element. The board member has a first surface that is opposite the mount surface and a second surface that is an opposite surface of the first surface and on which the light emitting element is mounted. The first surface of the board member is defined as a portion of the discharge cavity.

A display module and a tiled display device are provided. The display module includes a driving backboard and a heat dissipation component, wherein the driving backboard includes an underlaying substrate and a driving circuit disposed on the underlaying substrate, the underlaying substrate is provided with a flexible printed circuit board connected with the driving circuit, and the heat dissipation component is provided with an adapter component connected with the flexible printed circuit board, and the adapter component includes a pluggable connector.

An ultraviolet curing device and a control method thereof. The device comprises an ultraviolet light source and a controller connected by means of a cable. The ultraviolet light source is a water-cooled ultraviolet light source or an air-cooled ultraviolet light source. The controller is provided inside or outside of the ultraviolet light source. The ultraviolet light source comprises a shell (101), a copper substrate (103), multiple paths of LED chips (104), and a cooling assembly. The controller comprises a constant-current circuit board (105). The constant-current circuit board (105) performs multi-path constant -current control on the multiple paths of LED chips (104) to monitor anomaly of the voltage drop of the multiple paths of LED chip (104)s, thereby achieving control of the multiple paths of LED chips (104).

A light emitting device for a display including a first LED sub-unit, a second LED sub-unit disposed on the first LED sub-unit, a third LED sub-unit disposed on the second LED sub-unit, electrode pads disposed below the first LED sub-unit, and a filler disposed between the electrode pads, in which the electrode pads include a common electrode pad electrically connected in common to the first, second, and third LED sub-units, and first, second, and third electrode pads connected to the first, second, and third LED sub-units, respectively, the first, second, and third LED sub-units are independently drivable, light generated in the first LED sub-unit is configured to be emitted to the outside of the light emitting device through the second and third LED sub-units, and light generated in the second LED sub-unit is configured to be emitted to the outside through the third LED sub-unit.

A solid-state light source contains light emitting diodes. The elements are an inorganic light emitting diode chip and at least one wavelength conversion chip or the elements are a plurality of light emitting diode chips and one or more optional wavelength conversion chips. Both substantially parallel and orthogonal mounting configurations are used for the light emitting diodes. Orthogonal mounting or rib emitter is a preferred embodiment. The wavelength conversion chip may include an electrical interconnection means. The light emitting diode chip may include at least one GaN-based semiconductor layer that is at least ten microns thick and that is fabricated by hydride vapor phase epitaxy. Methods, equipment, and articles can be used to fabricate the solid-state light sources, freestanding foil based light emitting diodes, and wavelength conversion materials.

A light source. The light source includes as components which superimpose one another in this sequence: a first light-emitting semiconductor component; a first carrier element comprising a first carrier surface which faces the first light-emitting semiconductor component and a first cooling surface deliminating at least in part a first fluid path; and a distributor element comprising a first cavity and a further cavity. The first cavity and the further cavity are fluidically connected to one another by the first fluid path. Also disclosed are a printing machine; methods, in particular for producing a printed product, for irradiating a material to be irradiated, and for producing a light source; corresponding method products; an assembly having the light source; and uses of the light source.

Described herein are devices, systems, and methods for delivering phototherapy to a subject. A phototherapy light engine is combined with other components to form a phototherapy system that provides phototherapy treatment to a subject. A phototherapy system may be implemented as a hand held system comprising the light engine that is configured to communicate with a remote computing device.