Abstract: A startup stage protection device used in Electric Multiple Unit (EMU) train coupler experiment is provided between two test cars. The startup stage protection device is arranged between and tightly abuts two test cars at the starting stage of the experiment to receive a compressing force in place of the coupler. The startup stage protection device separates from the two test cars after the end of the starting stage.

Abstract: A white LED including red phosphor, at least one blue LED chip and at least one green LED chip, wherein a red light, a blue light and a green light are mixed simultaneously to produce a white light. The red phosphor comprises a first red phosphor and a second red phosphor. The first red phosphor is made from a substance having structure formula M2AX6:Mn4+, wherein the element M is selected from Li, Na, K, Rb or Cs, the element A is selected from Ti, Si, Ge or Zr, and the element X is selected from F, Cl or Br; the ratio of the second red phosphor to the red phosphor ranges from 0.01% to 15%. Further provided is a backlight module. The adjustably colored points of a device comprising M2AX6:Mn4+ are achieved by adding a second red phosphor to the red phosphor comprising M2AX6:Mn4+.

Abstract: A red luminophor, LED device and method for making the LED device. The red luminophor includes one or more materials selected from SrLiAl3N4:Eu2+, CaLiAl3N4:Eu2+, Sr4LiAl11N14:Eu2+ and Li2Ca2(Mg2Si2N6):Eu2+. The LED device includes the red luminophor. The method for making the LED device includes preparing a carrier; installing a blue LED onto the carrier; mixing the red luminophors and the transparent sealant to form a mixture; dispensing the mixture on the blue LED and the carrier to form an integration; and heating and curing the integration. The red luminophor has continuous light radiation in the wavelength range of 600 nm-750 nm, with the emission peak at 650-680 nm and the FWHM of less than 90 nm. Its emission light intensity at the wavelength of 730 nm is not less than 30% of its maximum emission light intensity, which matches the absorption needs of phytochrome of plant.

Abstract: A startup stage protection device used in Electric Multiple Unit (EMU) train coupler experiment is provided between two test cars. The startup stage protection device is arranged between and tightly abuts two test cars at the starting stage of the experiment to receive a compressing force in place of the coupler. The startup stage protection device separates from the two test cars after the end of the starting stage.

Abstract: A red luminophor, LED device and method for making the LED device. The red luminophor includes one or more materials selected from SrLiAl3N4:Eu2+, CaLiAl3N4:Eu2+, Sr4LiAl11N14:Eu2+ and Li2Ca2(Mg2Si2N6):Eu2+. The LED device includes the red luminophor. The method for making the LED device includes preparing a carrier; installing a blue LED onto the carrier; mixing the red luminophors and the transparent sealant to form a mixture; dispensing the mixture on the blue LED and the carrier to form an integration; and heating and curing the integration. The red luminophor has continuous light radiation in the wavelength range of 600 nm-750 nm, with the emission peak at 650-680 nm and the FWHM of less than 90 nm. Its emission light intensity at the wavelength of 730 nm is not less than 30% of its maximum emission light intensity, which matches the absorption needs of phytochrome of plant.

Abstract: A light emitting device, including a carrier, at least one first light-emitting diode fixed on the carrier for emitting a first color light, at least one second light-emitting diode fixed on the carrier for emitting a second color light, a first light converter coated on at least one first light-emitting diode for converting the first color light into a red light, and a second light converter coated on at least one second light-emitting diode for converting the second color light into a third color light. The first color light, the red light, the second color light and the third color light are mixed into a sunlight-like light. The light emitting device and method effectively enhance the light emission intensity of the red light, and solve the problems of the existing sunlight-like light, e.g. insufficient red light intensity or absence of red light.

Abstract: A red phosphor comprising a first red phosphor and a second red phosphor having adjustable wavelength. The first red phosphor is made from a substance having structure formula M2AX6:Mn4+, wherein the element M is selected from Li, Na, K, Rb or Cs, the element A is selected from Ti, Si, Ge or Zr, and the element X is selected from F, Cl or Br; the ratio of the second red phosphor to the red phosphor ranges from 0.01% to 15%. Further provided is a white LED and a backlight module. The adjustably colored points of a device including M2AX6:Mn4+ are achieved by adding a second red phosphor having various wavelength to the red phosphor including M2AX6:Mn4+ whose emission wavelength and spectral shape cannot be adjusted. The device can enable full range of colored points with hardly any reduction of the NTSC color gamut.

Abstract: A white LED including red phosphor, at least one blue LED chip and at least one green LED chip, wherein a red light, a blue light and a green light are mixed simultaneously to produce a white light. The red phosphor comprises a first red phosphor and a second red phosphor. The first red phosphor is made from a substance having structure formula M2AX6:Mn4+, wherein the element M is selected from Li, Na, K, Rb or Cs, the element A is selected from Ti, Si, Ge or Zr, and the element X is selected from F, Cl or Br; the ratio of the second red phosphor to the red phosphor ranges from 0.01% to 15%. Further provided is a backlight module. The adjustably colored points of a device comprising M2AX6:Mn4+ are achieved by adding a second red phosphor to the red phosphor comprising M2AX6:Mn4+.

Abstract: The present invention provide an light emitting device (LED) with wide color gamut (high NTSC), and a LED backlight module with the light emitting device, the light emitting device includes at least one LED chip, wherein the LED chip is a blue or ultraviolet (UV) LED chip, the light-out surface of the LED chip is covered by a phosphor-converted layer which consists of phosphor converted materials and thermosetting colloid materials, the phosphor converted materials contain green-converted phosphor, red-converted phosphor and a special phosphor material that has strong light-absorbing properties in the wavelength range of 460-510 nm. The present invention can reduce the stringent requirements of phosphor FWHM that needs to meet for conventional high NTSC solution.

Abstract: The present invention provide an light emitting device (LED) with wide color gamut (high NTSC), and a LED backlight module with the light emitting device, the light emitting device includes at least one LED chip, wherein the LED chip is a blue or ultraviolet (UV) LED chip, the light-out surface of the LED chip is covered by a phosphor-converted layer which consists of phosphor converted materials and thermosetting colloid materials, the phosphor converted materials contain green-converted phosphor, red-converted phosphor and a special phosphor material that has strong light-absorbing properties in the wavelength range of 460-510 nm. The present invention can reduce the stringent requirements of phosphor FWHM that needs to meet for conventional high NTSC solution.

Abstract: The present invention discloses a white LED chip and method of manufacturing the same. The white LED chip includes a flip blue LED chip and a preformed conversion layer for light conversion, the method of manufacturing the white LED chip includes the steps of preparing for a preformed conversion layer for light conversion, setting up at least one cavity on the conversion layer, for receiving a blue LED chip(s), attaching the blue LED chip into the cavity; and cutting the conversion layer into a single white LED chip based on each cavity that received a blue LED chip. The invention not only enhance the luminous efficiency of the white LED chip, but also avoid the pollution to bottom electrode of the LED chip, making easier manufacture and higher binning yield.