JP2005079500A - White light emitting device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a white light emitting device excellent in emitting characteristics. <P>SOLUTION: Two kinds of fluorescent materials are exited by a blue or bluish green light emitting diode whose wavelength range is 450 to 500 nm, then, fluorescent materials produces yellow fluorescence of a dominant wavelength 520 to 580 nm and vivid red fluorescence of dominant wavelength 580 to 640 nm respectively, and a white light emitting device excellent in emitting characteristics is attained by packaging the fluorescent materials and a package material at a predetermined mixing rate. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a high-intensity white light semiconductor light-emitting device, and in particular, high-intensity white light emission by combining two types of fluorescent powders capable of emitting yellow fluorescence and red fluorescence in a light emitting diode of blue light or blue-green light. The present invention relates to a technique for manufacturing a device.

  White light is multicolored mixed light, and light rays that are perceived as white light by human eyes are mixed light of at least two or more wavelengths. For example, when the human eye is simultaneously stimulated by light rays of red, blue and green, or when simultaneously stimulated by blue light and yellow light, it is all felt to be white light. Therefore, a white light semiconductor light emitting device can be manufactured according to this principle. A conventional method for manufacturing a white light semiconductor light-emitting device has the following five main techniques.

  The first type uses three light emitting diodes made of AlInGaP, GaP, and InGaN, and controls the current that flows through the light emitting diodes, thereby providing red light and green light respectively. And emit blue light. These three light-emitting diodes are arranged in the same lamp, and light of these three colors is mixed by a lens to emit white light.

  The second type uses two light-emitting diodes made of InGaN and AlInGaP or GaP, and controls the current flowing through each light-emitting diode, thereby allowing each light-emitting diode to emit blue light. Yellow light is emitted and mixed to produce white light. In view of the current technique level, the luminous efficiency of the above-mentioned types can reach 20 lm / W.

  The third type is a technique developed by Nichia Chemical Co., Ltd. in 1996. It is an Indium blue light emitting diode that can emit yellow light when stimulated. A garnet-type fluorescent powder is combined to create a white light source. At present, this kind of technique can reach the luminous efficiency of 20 lm / W or more. Further, in the case of this type of system, it is only necessary to use a set of light emitting diode chips, so that the manufacturing cost can be greatly reduced. At present, the preparation technology of the fluorescent powders used in combination with these has already matured, and products have been submitted.

  The fourth type is a white light-emitting diode made of a kind of ZnSe material proposed by Sumitomo Electric Industries Ltd. in January 1991. Sumitomo Electric Industries Ltd. According to this type of technique, a CdZnSe thin film is first formed on a ZnSe single crystal substrate, and the thin film emits blue light after energization. At the same time, a part of the blue light irradiates the substrate and emits yellow light. The white light is emitted by mixing with the complementarity of light and yellow light. This kind of method only needs to use a single light emitting diode crystal grain, its operating voltage is simply 2.7V, lower than 3.5V of GaN type light emitting diode, and no phosphor is used. White light can be acquired as it is.

  The fifth type is a technique of ultraviolet white light emitting diodes currently under development. The principle of this type of technique is to stimulate three or more types of fluorescent powder with an ultraviolet light-emitting diode to emit light of different colors, and mix the light to emit white light. is there.

  The common disadvantages of the first and second types are that normal white light cannot be acquired if one of the light emitting diodes of different colors fails. In addition, since the positive biases of the respective light emitting diodes are different, it is necessary to arrange a plurality of sets of control circuits, resulting in an increase in cost, which are all inconvenient factors in actual use.

  The second and third methods all acquire white light using the principle of color complementarity, and the continuity of the wavelength distribution of the vector does not reach true sunlight. When these color lights are mixed, a color non-uniform phenomenon occurs in the visible light spectrum range (400 nm to 700 nm), thereby reducing the saturation of the color. The human eye can see the white light ignoring the above phenomenon, but when it is detected by an optical detection device with a certain level of precision, for example, when using a video camera or an ordinary camera, the color rendering is performed. The nature is substantially lower, i.e., errors may occur when the color is reduced. Therefore, the white light source according to this method can be used only for simple illumination purposes.

  The fourth type has a drawback in that its luminous efficiency is only 8 ml / W. And its service life is only 8000 hours. From a practical point of view, it needs to be further broken down.

  Lastly, the fifth type improves the color rendering by producing a white light source with the visible light of three wave sections, and therefore uses three or more types of fluorescent powder. If you do, you can achieve its purpose. In order to cause multiple types of fluorescent powders to emit fluorescence of different wavelengths at the same time, the precondition is that the stimulating light to be used is just absorbed by those fluorescent powders, and each fluorescent powder is It is necessary to treat so that the coefficient for absorbing light of wavelength is not so discriminatory, and also to make the quantum efficiency of light energy as small as possible, and the types of fluorescent materials to which these causes apply In this case, it is difficult to select a fluorescent material.

  For this reason, the inventor of the present invention advances research and development, combines academic operations, improves the drawbacks of the prior art, breaks through the limitations of the prior art, reduces manufacturing difficulties, and The technique of the white light emitting device was acquired by making the excitation light source by combining one light emitting diode with the fluorescent powder.

  According to the white light emitting device of the present invention, it includes a light emitting diode capable of emitting blue light or blue green light, and yellow fluorescence having a main wavelength range of 520 to 580 nm when excited by the light emitted from the light emitting diode. A first phosphor and a second phosphor that is excited by a light beam emitted from the light emitting diode and generates red fluorescence having a dominant wavelength range of 580 to 640 nm. As described above, since white light is a light beam in which a plurality of types of color light is mixed, according to this optical color mixing principle, blue light or blue-green light emitted from a light emitting diode is mixed with yellow fluorescence and red fluorescence. This makes it possible for human eyes to feel like white light.

The chemical formula of the first phosphor is _{preferably, (Y x M y Ce z} ) is set to be the Al _{5 O 12,} Wherein, x + y = 3, and x, y ≠ 0, and 0.5> z > 0, and M is selected from the group consisting of metal elements such as Tb, Lu, Yb, among which (Y _x M _y ) Al ₅ O ₁₂ is set to be a main structure, and Ce is set to be the emission center.

The chemical formula of the second phosphor is preferably set to be (M ′ _a Eu _b ) S, in which a + b = 1 to 1.2, a, b ≠ 0, and M ′ is It is selected from the group consisting of metallic elements such as Ca, Sr, Ba, etc., and among them, it is set so that M ′S is the main structure and Eu is the emission center.

  In the white light emitting device of the present invention, a light emitting diode having a characteristic capable of saving electric energy is used as a light source of blue light or blue green light, and two kinds of fluorescent materials prepared by appropriate proportions are combined and packaged. When a very low current is applied later, a high-intensity white light-emitting diode with excellent light emission characteristics can be obtained.

  Since the fluorescent powder used in the white light emitting device of the present invention has a characteristic that the emission wavelength can be changed by changing the composition of the main crystal lattice, it emits blue or blue-green light having an appropriate wavelength. White light can be emitted by combining the diodes. In addition, since the fluorescent powder to be used can be synthesized by a simple solid reaction method, it is suitable for mass production and has high utility value in the polar industry.

  Compared with the case of using a plurality of types of fluorescent materials of a conventional white light emitting device, the present invention further has the following plurality of excellent points.

  1. In the current light-emitting diode, it is quite difficult to produce high-intensity blue light with a short wavelength in the production process, and the blue light to be combined with the fluorescent powder used in the white light-emitting device of the present invention is longer. It can be adjusted to the wavelength. Another advantage is that, when excited by blue light or blue-green light having a longer wavelength, the luminous efficiency can be higher than that of blue light having a shorter wavelength (470 nm or less).

  2. The method for adjusting the light color of the fluorescent powder used in the white light emitting device of the present invention is a method of changing the main crystal lattice. Compared with the conventional method of changing the amount of extraneous ions added, the proportion of extraneous ions that need to be added is lower, so there is a risk that the light color will be altered due to an error in the amount of raw material. On the other hand, the fluorescent powder used in the present invention does not have this kind of drawback and has favorable stability in the manufacturing process.

  The white light emitting device of the present invention uses a single light emitting diode as an excitation light source, and uses two types of phosphors that are excited by the two excitation light sources to generate different light colors. A high-intensity white light source is formed by mixing color rays. The light emitting diode used as the excitation light source is a blue light or blue green light emitting diode having an emission wavelength of preferably in the range of 450 to 500 nm, and excellent in the range of 470 to 500 nm. The two types of phosphors are a yellow phosphor and a red phosphor, respectively. When they are excited by the excitation light source, yellow fluorescence having a main wavelength range of 520 to 580 nm and a main wavelength range of 580 to 640 nm, respectively. Generates red fluorescence. Yellow phosphor and red phosphor are mixed or combined in different proportions with each packaging material, and when combined with blue light or blue green light emitting diode, each has different color temperature, luminance and color rendering properties, etc. A white light emitting device can be obtained.

The chemical formula of the yellow phosphor is _{preferably, (Y x M y Ce z} ) is set to be the Al _{5 O 12,} Wherein, x + y = 3, and x, y ≠ 0, and 0.5>z> 0 M is selected from the group consisting of metal elements such as Tb, Lu, Yb, among which (Y _x M _y ) Al ₅ O ₁₂ is set to be a main structure, and Ce is It is set to be the emission center. The chemical formula of the red phosphor is preferably set to be (M ′ _a Eu _b ) S, in which a + b = 1 to 1.2, a, b ≠ 0, and M ′ is Ca, It is selected from a group consisting of metal elements such as Sr and Ba, and among them, M ′S is the main structure and Eu is the emission center. These two types of phosphors are all set to have emission centers that emit fluorescence when excited by an external light source by allowing foreign ions to penetrate into the main structure. In addition, it all has one characteristic, that is, the light color of the phosphors is generated by fine-tuning the main constituent elements of the phosphors, and the crystal lattice field of the compound (Crystal Field) By adjusting the intensity, the distribution of the electron energy form at the emission center is modified. The emission wavelength is changed by making the difference.

  The manufacturing method of the white light emitting device of the present invention includes elements such as a fluorescent powder to be selectively used, a preparation technique thereof, and a packaging technique thereof. This will be described in detail.

1. Chemical formula _{(Y x} M _y Ce _z) were synthesized Al ₅ yellow phosphor _{O 12,} therein, x + y = 3, and x, y ≠ 0, and 0.5>z> 0, and M is Tb, It is selected from a group consisting of metal elements such as Lu and Yb, and as a synthesis method thereof, a chemical synthesis method, a solid reaction method, an organometallic thermal decomposition method, or the like can be adopted. yellow phosphor is _{(Y 0.8 Tb 2.2 Ce 0.05)} Al 5 O 12.

2. A red phosphor having _a chemical formula of (M ′ _a Eu _b ) S is synthesized, in which a + b = 1 to 1.2, a, b ≠ 0, and M ′ is a metal element such as Ca, Sr, Ba, etc. As a synthesis method thereof, a chemical synthesis method, a solid reaction method, an organometallic thermal decomposition method, or the like can be adopted. In this example, the synthesized red phosphor is (Sr _{0 .9} Eu _0.1 ) S.

  3. The two types of fluorescent powder and epoxy resin are mixed, and then a blue-green light emitting diode having a main wavelength of 480 nm is used as an excitation light source, and packaging is performed to obtain a white light emitting device.

  FIG. 1 shows a spectrum diagram of the above embodiment, in which spectrum A is an emission spectrum obtained by measuring the white light emitting device of the above embodiment. The spectrum of the obtained white light emitting device can be calculated as the actual spectrum preparation status of the single spectrum of each light source (light emitting diode and phosphor) by a computer program, as shown in FIG. While B is a spectrum of a light emitting diode, spectrum C is a spectrum generated by exciting a yellow phosphor, and spectrum D is a spectrum generated by exciting a red phosphor.

  As shown in FIG. 2, when the coordinate point A of the mixed color light of the white light emitting device is observed in the CIE color saturation coordinate diagram, it can be found that the color is indeed in the white area in the diagram.

  According to the present invention, a white light emitting device having different color temperatures, excellent color rendering properties and high luminance can be provided.

  Although the invention has been disclosed above by way of the foregoing examples and drawings, it should be appreciated that they are merely examples given and are not intended to limit the scope of the invention. The scope is defined by the scope of the claims, and it goes without saying that all changes and modifications of the effects implemented based on the gist of the present invention should fall within the scope of the present invention.

It is an emission spectrum figure of the Example of the white light-emitting device of this invention. FIG. 2 is a CIE color saturation coordinate diagram of the embodiment of FIG. 1.

Claims (5)

A light emitting diode capable of emitting blue or blue-green light;
A first phosphor that emits yellow fluorescence having a dominant wavelength range of 520 to 580 nm when excited by light emitted from the light emitting diode;
A second phosphor that emits red fluorescence having a dominant wavelength range of 580 to 640 nm when excited by light emitted from the light emitting diode;
The white light emitting device, wherein the light emitted from the light emitting diode is set to emit white light by mixing the yellow fluorescent light and the red fluorescent light.   2. The white light emitting device according to claim 1, wherein a wavelength range of light emitted from the light emitting diode is set to be 450 nm to 500 nm, preferably set to 470 nm to 500 nm. The chemical formula of the first phosphor is set to be _{(Y x M y Ce z)} Al 5 O 12, therein, x + y = 3, and x, y ≠ 0, and 0.5>z> 0, M is selected from the group consisting of metal elements such as Tb, Lu, and Yb. Among them, (Y _x M _y ) Al ₅ O ₁₂ is set as the main structure, and Ce emits light. The white light emitting device according to claim 1, wherein the white light emitting device is set to be centered. The chemical formula of the second phosphor is set to be (M ′ _a Eu _b ) S, in which a + b = 1 to 1.2, a, b ≠ 0, and M ′ is Ca, Sr, Ba 2. The white color according to claim 1, wherein M ′S is a main structure and Eu is a light emission center. Light emitting device.   The first phosphor and the second phosphor are mixed or combined in proportions different from those of the packaging material, and are used in combination with a light emitting diode of blue light or blue green light. The white light emitting device according to claim 1, wherein light emitting characteristics such as temperature, luminance and color rendering properties are imparted.

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