55results about How to "Expand the luminous area" patented technology

The invention relates to the technical field of liquid crystal display, in particular to a backlight module and a liquid crystal displayer. The backlight module sequentially comprises a printed circuit board, a reflector plate, an LED light source and a diffusion plate from bottom to top. First protruding points are arranged on the light-in face, facing the LED light source, of the diffusion plate and around the projection, within the light-in face, of the LED light source. The first protruding points can conduct reflection diffusion on an illumination area, on the diffusion plate, of the LED light source, eliminate projection dark spaces and prevent light source gathering, so that the distribution of a light-emitting area on the diffusion plate is more uniform. Meanwhile, the LED light source can be independently controlled, local light control can be better achieved, and accordingly the display quality of a high-dynamic-comparison image is improved. The reflector plate can reflect leaking light again so that the light can irradiate the diffusion plate again, accordingly the utilization rate of the light source is increased, the light mixing distance is increased, and thinning design of the liquid crystal displayer is achieved easily.

The luminous fabric device includes one pattern layer and one optical fiber fabric layer. The pattern layer consists of one transparent area and one opaque area and forms the displayed pattern. The optical fiber fabric layer is woven with optical fibers and yarns and is used to provide light source for the luminous fabric device. The optical fiber fabric layer is fixed to the pattern layer through sewing or through one fixing assembly.

The invention mainly aims at disclosing a light-emitting element which comprises a semiconductor stack, wherein the semiconductor stack comprises an active layer, the active layer is in a multiple quantum well (MQW) structure formed by stacking a plurality of quantum well layers and a plurality of barrier layers in a staggered manner, and the plurality of the barrier layers comprise at least one doped barrier layer and one undoped barrier layer. Therefore, the doped barrier layer can improve the carrier mobility of a hole, uniformize a light-emitting region in the active layer and improve the internal quantum efficiency (IQE) of the light-emitting element.

The invention discloses an LED (light-emitting diode) chip with a novel structure and a production method of the LED chip, and belongs to the field of a semiconductor device. The LED chip structure comprises an N-side electrode, a substrate, an active layer, a gallium phosphide layer, an indium-gallium-phosphorus layer, a P-side soldering wire electrode, an expanded electrode and a current barrier groove. The production method comprises the steps: growing the indium-gallium-phosphorus layer with the thickness of 1000 angstroms on a P side of a chip, etching and coarsing the gallium phosphide layer, evaporating the P-side soldering wire electrode and the expanded electrode by utilizing a vacuum film coating technology, etching the current barrier groove by virtue of plasma, and facilitating the ohm contact between the expanded electrode and the gallium phosphide layer in virtue of alloy. By adopting the produced LED chip, the current can be expanded to the entire chip surface through the expanded electrode, so that the effective application of the current is improved; meanwhile, by adopting the surface coarsing, the light emitting rate of the chip can be effectively improved. The LED chip has the advantages of simplicity in structure, simple and feasible production method and easiness in manufacturing.

The invention requests and protects a dual-light emitting layer structure blue-light OLED device and a manufacturing process thereof. The device comprises a positive electrode substrate, a hole injection layer, a hole transmission layer, a first light-emitting layer, a second light-emitting layer, an electronic transmission layer, an electronic injection layer and a negative electrode, wherein the first light-emitting layer and the second light-emitting layer employ the same main body materials, same object material and same thickness, and the object doping concentration of the first light-emitting layer is not higher than 50% of the object doping concentration of the second light-emitting layer. The dual-light emitting layer structure provided by the technical scheme is simple, the exciton utilization rate and the composite region can be expanded, and the efficiency roll-off of the device is effectively improved.

The invention discloses a light-expanding imaging device for eliminating moire of an LED (Light Emitting Diode) display screen. The light-expanding imaging device comprises a mask base plate and a light-expanding imaging dielectric slab, wherein the mask base plate is provided with a plurality of light-conducting cavities; the light-conducting cavities are arranged as back tapered holes with square cross sections; point light sources are arranged at the bottom of the light-conducting cavities; the light-expanding imaging dielectric slab is covered on the top surfaces of the light-conducting cavities of the mask base plate; the LED display screen is totally covered by the light-expanding imaging device provided by the invention, so that the point light sources can be turned into area light sources after the light emitted from the luminous points is subjected to the treatment, such as, the light conduction of the light-conducting cavities, the light emission of the walls of the light-conducting cavities, the light absorption, light filtering, color mixing and scattering of the light-expanding imaging dielectric slab, and the like, after the LED display screen is lightened; the luminous points are imaged on the surface of the light-expanding imaging dielectric slab after the light conduction of the light-conducting cavities, the light radiation of the walls of the light-conducting cavities and the color mixing treatment and scattering of the light-expanding imaging dielectric slab, the continuous light is formed, the grid structure and the granular sensation of the luminous points are eliminated, the moire generating conditions of a digital video (or camera) and the LED display screen are eliminated and the effect of eliminating the moire is good.

The invention discloses an LED display screen moire-eliminating and color-mixing face cover which is composed of a face cover bottom plate and a plurality of color mixing devices. A plurality of embedment grooves are formed in the face cover bottom plate. The color mixing devices are embedded in the embedment grooves in the face cover bottom plate. Due to the fact that the non-luminance areas between LED display screen luminance points are all covered with the face cover, after an LED display screen is turned on, light absorbing, light filtering, color mixing, scattering and other processing are conducted on light emitted by the luminance points through the color mixing devices, color-mixed light is scattered on the surfaces of all the color mixing devices, and therefore the non-luminance areas of the LED display screen all become luminance areas, and the luminance areas and light mixing areas of LED tube cores are enlarged. The luminance points form continuous light on the surfaces of the color mixing devices after color mixing and scattering are conducted on light through the color mixing devices, and therefore the grid structure and granular sensation of the luminance points are eliminated, the moire interference to LED display images shot by a digital camera or a camera is eliminated, and the moire eliminating effect is good.

The invention relates to the technical field of organic electroluminescence, and especially relates to a compound, an organic light-emitting device and a display device. The compound has a structure represented by formula (I).

The invention discloses a lamp. The lamp (10) comprises a body (11) and a light-emitting device (12) which is mechanically and electrically connected with the body, the light-emitting device (12) comprises at least two light-emitting modules (121, 122, 123 and 124), at least one of the light-emitting modules (122, 123 and 124) of the at least two light-emitting modules can move between the retracting position and the unfolding position, and therefore the light-emitting device (12) has various light-emitting areas with different areas. Besides, the lamp is very compact in structure when the light-emitting device is completely retracted.

The invention provides a circular-emitting lamp which comprises a base, a light source, a side wall and a top cover, wherein the side wall is fixed on the base; the top cover is fixed on the side wall; the base, the side wall and the top cover form an enclosed cavity together; the light source is arranged on the base in the cavity; one surface of the top cover positioned in the cavity is a reflection surface capable of reflecting light rays; the reflection surface is an indent or convex arc surface; and the side wall is transparent, and scattering dots are distributed on the inner surface and/or the outer surface of the side wall. The emitting region is wide for the circular-emitting lamp, and the light ray uniformity and continuity are high.

A light-emitting diode (LED) structure and a method for manufacturing the same. In one embodiment, the LED structure includes a carrying component, an LED chip, a first conductivity type electrode and a second conductivity type electrode. The carrying component includes a carrier, a sidewall disposed on the carrier and forms a carrying tank. The LED chip is fixed within the carrying tank and includes a first conductivity type semiconductor layer having a first region and a second region, an active layer and a second conductivity type semiconductor layer stacked in sequence. The LED chip further includes a second conductive finger disposed on the second semiconductor layer in the first region, and a first conductive finger disposed on the first semiconductor layer in the second region. The first electrode extends on the sidewall and the first conductive finger. The second electrode extends on the sidewall and the second conductive finger.

A semiconductor light emitting device may include: a first conductive type nitride semiconductor layer; an active layer formed under the first conductive type nitride semiconductor layer; a second conductive type nitride semiconductor layer formed under the active layer; mesa regions formed upward from the second conductive type nitride semiconductor layer so as to expose the first conductive type nitride semiconductor layer; a second electrode formed under the second conductive type nitride semiconductor layer; a cover metal layer formed at a corner under the second conductive type nitride semiconductor layer so as to overlap a part of the second electrode, and partially exposed in the upward direction; an insulating layer formed under the cover metal layer, the second electrode, and the mesa regions; openings of the insulating layer, formed at portions corresponding to the mesa regions so as to expose the first conductive type nitride semiconductor layer; a first electrode formed under the insulating layer and in the openings; a conductive substrate formed under the first electrode; and a second electrode pad formed over the exposed cover metal layer.

The invention relates to an LED lamp. The LED lamp comprises a tube and a metal lamp holder capable of being used for high-frequency heating, wherein the tube comprises a straight part and necked parts arranged at two ends of the straight part, and smooth transition sections are arranged between the necked parts and the straight part; a lamp belt adheres to the straight part by the aid of an adhesive, and a patch power supply and LED light-emitting units are arranged on the lamp belt; the metal lamp holder is arranged outside the necked parts and is closely connected with the necked parts by the aid of welding mud; the metal lamp holder is 10-12 mm long, the necked parts are 6-8 mm long, and the gap between the metal lamp holder and the necked parts is 1-2 mm; the patch power supply is arranged in the position close to one end of the straight part, and the distance between the patch power supply and the end of the straight part is 3-5 mm. The LED lamp is simple in structure, high in lighting efficiency and low in rejection rate, comprises few components, is beneficial to industrial production line production and has unique technical advantages in aspects of breaking through the production bottleneck and substantially increasing the profit margin of products, and the welding mud is efficient and quick to solidify.

The invention discloses an organic electroluminescence display panel, a manufacturing method thereof and a display device. The organic electroluminescence display panel comprises a substrate, an anode, a cathode, an organic light-emitting layer and a semiconductor layer, wherein the anode and the cathode are located on the substrate, the organic light-emitting layer is located between the anode and the cathode, and the semiconductor layer covers the whole substrate; the semiconductor layer is located between the anode and the organic light-emitting layer or between the cathode and the organic light-emitting layer. The organic electroluminescence display panel has the advantages that a pixel definition layer in the prior art can be omitted, and pixel light-emitting areas can be increased.

The invention discloses a thick-wall part structure, a light-emitting device and a light-emitting mode. The thick-wall part structure comprises a light guide structure body, and the light guide structure body is provided with a light source incident plane, a first reflecting plane set, a second reflecting plane set and a light-emitting plane perpendicular to the light source incident plane; the first reflecting plane set is suitable for reflecting incident light in a plane perpendicular to the light-emitting plane and the light source incident plane and forming a central light-emitting area on the light-emitting plane; and the second reflecting plane set diverges the incident light towards two opposite sides parallel to the light-emitting plane, and forms a diffusion light-emitting area on the light-emitting plane, so that the light-emitting width on the light-emitting plane is greater than the width of the light source incident surface. Light emitting of the central area is guaranteed, meanwhile, the diffusion light emitting area is added, the light emitting width is larger than the initial irradiation width of the light sources, when the distance between the light sources is large, the area between the two light sources can be completely irradiated, dark areas are avoided, and the uniform light emitting requirement of customers is met.