RU2214073C2 - White light source - Google Patents

Abstract

FIELD: lighting engineering, integrated circuits for microelectronics and electronic material science. SUBSTANCE: white light source built around blue-color nitridegallium light-emitting diode is so designed that blue light is partially converted into yellow light by means of luminescent converter assembled of single-crystalline piles on transparent substrate, then blue and yellow rays are mixed up to generated white light. EFFECT: enhanced efficiency of phosphor conversion, eliminated phosphor degradation, improved environmental friendliness. 6 cl, 5 dwg _

Description

FIELD OF THE INVENTION
The present invention is in the field of lighting engineering, element base of microelectronics and electronic materials science.

BACKGROUND OF THE INVENTION
A known white light source in the form of a fluorescent lamp in which ultraviolet radiation excited by a low-pressure gas discharge in mercury vapor is converted by means of a phosphor into visible light, including white radiation [1].

However, fluorescent lamps have several disadvantages:
(a) mercury vapors are environmentally unacceptable: in case of destruction of the lamp bulb and at the stage of their production;
(b) the efficiency of fluorescent lamps (about 12 lumens / watts), although they exceed the efficiency of incandescent lamps (about 5 lumens / watts), is still insufficient.

 It is known about the use of solid-state semiconductor LEDs based on gallium nitride and related compounds as light sources [2]. In such devices, the short-wave (blue) light emitted by the LED is partially converted by the phosphor into a longer-wave (for example, yellow) light and, when mixed with the source, gives white radiation.

The efficiency of such light sources is highly dependent on the conversion efficiency of the phosphor. Standard phosphors are formed by a combination of small (micron and submicron size) crystalline grains, approximately isometric in shape, arranged randomly on top of each other, as shown in Fig. 1. In particular, a fine-grained phosphor based on Y ₃ Al ₃ Ga ₂ O ₁₂ : Ce is used in [2]. This phosphor is distributed in an organic bundle. Such a phosphor, absorbing the primary (blue-blue) radiation of an LED, emits (generates) yellow light with a wavelength of 565 nm. The superposition of these two radiation (primary and generated in the phosphor) allows to obtain white radiation.

 However, when propagating through a phosphor, the excited light, like the original light, is scattered by the grains and partially lost. As a result, conversion efficiency is reduced, often significantly.

 Another disadvantage of the luminescent converter used in [2] is that, due to the low thermal conductivity of the organic binder, the phosphor of the converter degrades when it overheats.

 These disadvantages can be largely eliminated in the present invention.

SUMMARY OF THE INVENTION
A white light source comprising an LED and a luminescent converter is provided, the converter being formed by single crystal phosphor columns arranged on a transparent substrate. The columns are mutually parallel, form angles from 10 ^° to 90 ^° with the substrate, have sections of different shapes, and the height of the columns exceeds their diameter. The columns have gaps between themselves, which can be filled with highly refractory substance. The converter is located on the output surface of the LED and is connected optically through an immersion medium having a refractive index lower than the refractive index of the phosphor. The LED is made to emit light in the wavelength range of 440-480 nm, and the transducer is made to emit light in the range of 560-590 nm with the ratio of the yellow light energy generated by the converter to the power of the stored blue light energy after the light has passed through the columns in excess of 2: 1.

 The ratio of the height of the columns to their diameter is at least 2.

 The converter can be turned to the surface of the LED either with a substrate or with columns.

The volume of the columns occupies at least 90% of the volume of the transducer, and the absorption coefficient of the phosphor columns exceeds 10 ⁶ m ^-1 .

BRIEF DESCRIPTION OF THE FIGURES
Figure 1. Schematic of a standard phosphor consisting of approximately isometric crystalline grains.

 Figure 2. Scheme of light propagation in columnar crystals.

 Figure 3. Scheme of a white light source containing an LED, a luminescent converter and an immersion transition layer: 1 - LED; 2 - immersion layer; 3 - transparent substrate; 4 - luminescent columns; 5 - gaps between the columns, filled with fusible material.

 FIG. 4. Two options for the location of the converter: (a) columns to the LED; (b) a substrate for the LED.

BEST MODE FOR CARRYING OUT THE INVENTION
In the proposed white light source comprising an LED and a luminescent converter, light propagating through the phosphor is channelized by passing it through elongated grains of the phosphor. This effect is achieved when using phosphors with a columnar structure (luminescent columns), proposed in the patents [3, 4]. In such phosphors, light propagates along the luminescent columns, reflected from its walls according to the principle of total internal reflection (Fig. 2), and experiences only slight losses.

 In addition, there is no organic ligament in columnar phosphors.

The scheme proposed in the present invention, a white light source is shown in Fig.3. Between the LED and the converter there is an immersion layer, which can contain various transparent substances, such as organosilicon liquids, polymers, epoxies, fusible salt eutectics of the type KCl + NaCl + LiCl + MgCl ₂ and others.

 Light from the LED enters the ends of the columns through the immersion layer and propagates along them according to the principle of total internal reflection.

 The part of each of the columns adjacent to the indicated ends is formed by a phosphor that does not absorb (or weakly absorb) blue light, so that almost all of it (or a significant part of it) propagates further along the column.

 The part of each of the columns, which is removed from these ends, is formed by a phosphor capable of converting blue light into "additional" yellow light to it.

 Thus, in accordance with this invention create combined composition luminescent columns, which are able to provide any desired ratio of the remaining blue light and light converted to yellow. In particular, to ensure a white glow, the ratio of the power of the yellow light energy created by the luminescent converter to the power of the stored blue light energy after passing through the columns should be more than 2: 1.

 Luminescent columns are formed of light-conducting and heat-conducting inorganic matter. They have a sufficiently large contact area mounted on an inorganic substrate (for example, glass), which ensures high thermal conductivity of the entire structure and gives additional advantages to the luminescent converter with high LED power. This advantage is also achieved by the fact that the total volume of light-generating and light-emitting columns is at least 90% of the total volume of the converter. The rest of it (the gaps between the columns) can also be filled with a substance - fusible material.

The high lighting parameters of the proposed light source are due to the fact that it provides good spectral matching between the wavelength of the LED (450-480 nm) and the maximum excitation spectrum of the luminescent converter (440-475 nm). In addition, the absorption coefficient of the phosphor used (10 ⁶ -5.10 ⁶ m ^-1 ) allows even at a small height of the luminescent column (of the order of several micrometers) to achieve a sufficiently high (more than 50-60%) absorption of the primary blue radiation of the gallium nitride LED. At a photoluminescence quantum yield of about 1, approximately 70% (by the number of quanta) of yellow radiation is formed as a result of such absorption, and, in combination with the remaining about 30% of blue radiation, it is possible to obtain bright white light, i.e. the ratio of the power of the yellow light energy created by the converter to the power of the stored blue light energy after the light has passed through the columns exceeds 2: 1.

It is proposed to use, for example, a solid solution of ZnS: CdS = 90%: 10%, activated by copper with a copper concentration of 1.10 ^-3 to 1.10 ^-2 g / g (gram Cu / gram ZnS: CdS) as a suitable material for a luminescent converter. For the manufacture of columnar phosphor, it is proposed to use the method of vapor deposition described in the patents [3, 4]. After the columns are deposited, the obtained columnar structure from the side of the free ends of the columns is poured with fusible material, for example, based on Bi ₂ О ₃ -В ₂ О ₃ , is ground and polished.

 As follows from FIG. 4, the luminescent converter can be superimposed on the radiating surface either by luminescent columns to the LED (FIG. 4a) or by a substrate to the LED (FIG. 4b).

The fields of application of the proposed light source are numerous:
- light sources for domestic and industrial purposes;
- luminous scales;
- dot static and dynamic indicators of a running line;
- multi-element situational screens;
- others.

LITERATURE
1. Encyclopedic dictionary "Electronics". M .: Soviet Encyclopedia, 1991, p. 258.

 2. R. Dixon. Who's Who in Blue and Green LEDs, Compound Semiconductor 5 (1999) # 5, pp. 15-19.

 3. E.I. Givargizov, L.A. Zadorozhnaya, A.N. Stepanova, N.P. Soshchin, N.N. Chubun and M.E. Givargizov, Method for the manufacture of luminescent screens with a columnar structure. RF patent 2127465 C1, 6 H 01 J 29/18 (1999).

 4. E.I. Givargizov, L.A. Zadorozhnaya, A.N. Stepanova, N.P. Soshchin, N. N. Chubun and M. E. Givargizov. Cathodoluminescent screen with a columnar structure, and the method for its preparation, WO 99/22394 (1999).

Claims (6)

1. A white light source containing an LED and a luminescent converter, characterized in that the converter is formed by single-crystal phosphor columns located on a transparent substrate, the columns are mutually parallel, form angles of 10 ^o - 90 ^o with the substrate, have cross-sections of different shapes, the height of the columns exceeds them diameter, the columns have gaps between them that can be filled with highly refractory substance, the converter is located on the output surface of the LED and is connected optically through the immersion an ionic medium having a refractive index lower than the refractive index of the phosphor, wherein the LED is emitting light in the wavelength range of 440-480 nm, and the converter is emitting light in the range of 560 - 590 nm with respect to the power of yellow light energy generated by the converter to the power of stored energy blue light after passing light columns exceeding 2: 1.  2. The light source according to claim 1, characterized in that the ratio of the height of the columns to their diameter is not less than 2.  3. The light source according to claim 2, characterized in that the converter faces the surface of the LED substrate.  4. The light source according to claim 2, characterized in that the Converter faces the surface of the LED bars.  5. The light source according to claim 1, characterized in that the volume of the columns occupies at least 90% of the volume of the converter. 6. The light source according to claim 1, characterized in that the absorption coefficient of the phosphor columns exceeds 10 ⁶ m ^-1 .

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