WO2009039801A1 - Radiation-emitting component with conversion element - Google Patents

Abstract

The invention relates to a component with an LED chip (1), which is suitable for emitting an electromagnetic primary radiation, with a first conversion layer (9), which is applied on at least one main face of the LED chip (1) and which has at least one conversion element (10) which is suitable for converting a portion of the primary radiation into a secondary radiation, and with a second conversion layer (13), which is arranged after this first conversion layer (9) and which has at least one conversion element (11) which converts at least one portion of a primary radiation emitted by the LED chip (1) into a secondary radiation, wherein at least one portion of the secondary radiation from the conversion element (10) of the first conversion layer (9), a portion of the secondary radiation from the conversion element (11) of the second conversion layer (13) and a portion of the unconverted primary radiation are superimposed to form a mixed radiation, with colour inhomogeneities being reduced over the angle of radiation.

Description

 description

Radiation-emitting component with conversion element

This patent application claims the priorities of German patent application 10 2007 046 612.0 and German patent application 10 2007 057 710.0, the disclosure of which is hereby incorporated by reference.

The invention relates to a radiation-emitting component with a conversion layer arrangement according to claim 1.

Light-emitting components with a conversion element are known, for example, from WO 97/50132. These arrangements comprise a semiconductor body which emits light in operation (primary light), and a conversion layer with a conversion element which converts part of this light into another wavelength range (secondary light). The color impression of the light emitted by such a semiconductor component results from additive color mixing of primary light and secondary light.

The conversion element can be arranged downstream of the semiconductor in various ways. For example, the conversion layer consists of a potting compound surrounding the semiconductor body, in which the conversion element is embedded.

When such casting compounds are used, variations in color location may occur due to an inhomogeneous distribution of the conversion element in the casting compound, which may be due, for example, to sedimentation of conversion element particles. In the following, the term "color locus" refers to the numerical values which describe the color of the emitted light of the component in the CIE color space.

Furthermore, the semiconductor body as a source of primary light and the casting compound with conversion element as a source of secondary light are generally of different shape and size, so that a spatially inhomogeneous color impression can occur and chromatic errors may occur in images. In addition, there are manufacturing tolerances in the metering of the potting compound, which can lead to fluctuations in the amount of the potting compound, which is arranged downstream of the semiconductor body in a radiation direction, and thus also to fluctuations in the color locus of the component. If a uniform color impression is required in different directions of observation, then the optical path length in the potting compound should be approximately the same for all desired observation directions.

In the case of components with conventional LED chips, it has been found that the resulting color locus still has a dependence on the viewing angle if the semiconductor layer sequence of the LED chip is essentially provided with a thin, as homogeneous as possible and completely applied on the main surface of the semiconductor layer sequence conversion layer.

In WO 01/65613 A1 it is disclosed to apply a thin conversion layer with at least one conversion element directly on a semiconductor layer sequence of a diode chip. This has the advantage over the use of conversion element-containing potting compounds that the conversion element is more homogeneous and in a better definable amount can be applied to the semiconductor layer sequence of the diode chip. As a rule, a light emitted by diode chips of this type has a greater homogeneity with regard to its color local spectrum than components in which a diode chip is encapsulated with a casting compound containing conversion elements.

Such conversion of the light through a thin conversion layer directly above the semiconductor body results in that only certain color loci, e.g. can be set for an entire chip wafers, which themselves have fluctuations and tolerances in the color location. In addition, color differences over the emission angle may also occur due to different path lengths of the radiation.

It is an object of the present invention to provide a radiation-emitting component of the type mentioned, with which it is possible to realize a color spectrum with further improved homogeneity.

This object is achieved by a radiation-emitting component with the features of claim 1. Advantageous embodiments and preferred developments of the device are the subject of the dependent claims.

According to the invention, a radiation-emitting component contains an LED chip which emits primary radiation having a wavelength λ ₀ , wherein the LED chip is followed by a first conversion layer in the emission direction, which contains at least one conversion element which, upon excitation with the wavelength λ _{0, has} secondary radiation emitted at different wavelengths. In this case, the first conversion layer is applied at least on one main surface of the LED chip, wherein the first conversion layer is followed by a second conversion layer having at least one conversion element which emits secondary radiation of a different wavelength when excited at the wavelength λ ₀ , such that the semiconductor component mixed radiation emits, the primary radiation, secondary radiation of the conversion element of the first conversion layer and secondary radiation of the conversion element of the second conversion layer contains.

The component has the advantage that color differences over the emission angle of the LED chip, which result from different path lengths of the primary and secondary radiation, are reduced. This is due to the fact that at the conversion element of the second conversion layer, a part of the primary radiation and the secondary radiation of the first conversion layer are scattered, wherein the scattered radiation of the primary and secondary radiation propagates undirected in all spatial directions. As a result, fluctuations in the color locus above the Abstrahlwinke1 can be reduced. In this way, a reduction of Farbinhomogenitäten is achieved over the Abstrahlwinke1.

In the production of the component, by using two conversion layers, a close and adapted color selection can take place and thus a desired color location of the emitted radiation of the component can be set. By directly applied to the LED chip first conversion layer, a base Farbort can be adjusted, which essentially the color impression of the emitted Radiation of the device determined. The subsequent second conversion layer can be used to achieve a finer adjustment and thus a further adaptation of the color locus of the emitted radiation of the component.

In a preferred embodiment, the first conversion layer is thinner than the second conversion layer.

Preferably, the concentration of the conversion element in the second conversion layer is less than the concentration of the conversion element in the first conversion layer.

Due to the preferably low concentration of the conversion element of the second conversion layer, the original color location of the mixed radiation passing through the first conversion layer consisting of primary radiation and secondary radiation of the conversion element of the first conversion layer is only slightly changed. The color impression of the radiation emitted by the component is generated by the first conversion layer thus slightly influenced by the second conversion layer with low concentration of the conversion element contained therein. In combination with scattering effects on the conversion element of the second conversion layer, the overall result is a reduction of color inhomogeneities over the emission angle.

Preferably, the LED chip is arranged in a recess of a base housing, wherein the recess is at least partially filled by the second conversion layer and encloses at least a portion of the LED chip.

Preferably, the device has a reflector for the emitted from the LED chip in operation primary radiation and the generated secondary radiation, in which the LED chip and the subsequent conversion layers are at least partially arranged. Preferably, the reflector is formed by a reflection-increasing coating of the inner walls of the recess.

In an advantageous embodiment of the invention, the conversion element of the second conversion layer may be a part of the primary radiation in radiation of several

Convert wavelength ranges from mutually different spectral sub-areas, so that the component emits mixed radiation, consisting of primary radiation, secondary radiation of the first conversion layer and secondary radiation of the different wavelength ranges of the second conversion layer. As a result, it is advantageously possible to produce a variety of color mixtures and color locations.

The one or more wavelength ranges of the secondary radiation of the first and / or second conversion layer have substantially longer wavelengths than the wavelength range of the primary radiation.

With particular advantage, at least a part of the secondary radiation of the second conversion element has the same wavelength as the secondary radiation of the first conversion element. This increases the proportion of secondary radiation in the wavelength range of the conversion element of the first conversion layer. The color location of the radiation emitted by the component is thereby shifted in the direction of the secondary radiation. In the production of a component with two conversion layers in which the secondary radiation of the second conversion element has the same wavelength as the secondary radiation of the first conversion element, the color location of the mixed radiation emitted by the LED chip consisting of primary radiation and secondary radiation can otherwise be too strong the color location the primary radiation would be adjusted by the second conversion layer with advantage so that the color location of the radiation emitted by the component is shifted in the direction of the color locus of the secondary radiation.

Preferably, the conversion element or the conversion elements and LED chip are matched to one another such that the colors of the primary radiation and at least a part of the secondary radiation are complementary to one another. Additive color mixing gives the impression of white light.

With special advantage, the second conversion layer contains a further conversion element or further conversion elements, preferably red phosphors.

Due to the red phosphors in the second conversion layer, the color locus of the radiation emitted by the component is preferably in the color locus of a warm white distribution, which is preferably in the CIE color space in the color temperature range of 6000K - 2000K.

In the production of a component, by applying the second conversion layer, a color locus, which due to the conversion in the first conversion layer in the range of a white distribution, in the CIE color space in the Color temperature range of about 6000K, in the direction of different warm white distributions, which are preferably in the CIE color space in the color temperature range of 6000K - 2000K, are moved. Furthermore, it is possible by other conversion elements to produce blue, green, yellow or violet tones.

The wavelength of the radiation emitted by the LED chip is preferably in the ultraviolet or blue spectral range. Particularly suitable for this purpose are LED chips based on nitride compound semiconductors.

"Based on nitride compound semiconductors" in the present context means that the active epitaxial layer sequence or at least one layer thereof comprises a nitride III / V compound semiconductor material, preferably Al _n Ga _m inn _nm N, where 0 <n <1, 0 <m <1 and n + m <1. In this case, this material does not necessarily have to have a mathematically exact composition according to the above formula, but it may have one or more dopants and additional constituents which have the characteristic physical properties of the Al _n Ga _m Ini - _n - _π, N-material does not substantially change the sake of simplicity, however, the above formula includes only the major components of the crystal lattice (Al, Ga, in, N), even though these can be replaced in part by small amounts of other substances..

Alternatively, the layer sequence of the LED chip may be based on phosphide compound semiconductors. In this context, "based on phosphide compound semiconductors" means that the semiconductor body, in particular the active region, preferably comprises Al _n Ga _m Ini _-m P, where O _{≦ n ≦} l, O _{≦ m ≦} l and n + m <1 , preferably with n ≠ 0 - S -

and / or m ≠ 0. This material does not necessarily have to have a mathematically exact composition according to the above formula. Rather, it may include one or more dopants as well as additional ingredients that do not substantially alter the physical properties of the material. For the sake of simplicity, however, the above formula includes only the essential constituents of the crystal lattice (Al, Ga, In, P), even though these may be partially replaced by small amounts of other substances.

In a preferred embodiment of the invention, which is particularly suitable for generating mixed-colored light, the secondary radiation of the conversion element of the first and / or second conversion layer is in the yellow or red spectral range.

The LED chip is with particular advantage a thin-film LED chip. In the context of the application, an LED chip is considered a thin-film light-emitting diode chip, during the manufacture of which the growth substrate on which a layer sequence for the LED chip has been grown, for example epitaxially, is thinned or, in particular, completely detached.

A basic principle of a thin-film light-emitting diode chip is described, for example, in I. Schnitzer et al. , Appl. Phys. Lett. 63 (16), 18 October 1993, 2174-2176, the disclosure content of which is hereby incorporated by reference.

Preferably, the second conversion layer is formed by a potting compound, in which the second conversion element is embedded. With particular advantage, the component has a beam-shaping element in the emission direction. The emission characteristic of the component can thereby be advantageously influenced. For example, this element may be a lens.

Advantageously, in such a device, a small lens can be used as the beam-forming element without significant dispersion effects. This is due to the fact that preferably the concentration of the conversion element in the second conversion layer is lower than in the first conversion layer. Due to the low concentration of the conversion element in the second conversion layer, a small number of scattering effects of the primary and secondary radiation take place at the conversion elements in the second conversion layer. Thus, the emission surface of the radiation emitted by the LED chip is advantageously essentially predetermined by the LED chip and by the thin first conversion layer applied to the surface of the LED chip.

Further features, advantages, preferred embodiments and expediencies of the component emerge from the exemplary embodiments explained below in conjunction with FIGS. 1 and 2.

Show it:

Figure 1 is a schematic sectional view of a first embodiment of a device according to the invention, and

Figure 2 is a schematic sectional view of a second embodiment of a device according to the invention. The same or equivalent components are each provided with the same reference numerals. The components shown and the size ratios of the components with each other are not to be considered as true to scale.

In the case of the radiation-emitting component shown in FIG. 1, an LED chip 1 has a rear contact 2, a front contact 3 and a layer sequence 7 composed of a number of different layers, which contains an active zone which during operation of the component comprises at least one radiation (FIG. eg ultraviolet, blue or green).

The layer sequence 7 is based, for example, on nitride compound semiconductors, ie it preferably contains Al _x In _v Ga; L_ _x _yN, where O ≦ _x ≦ l, O ≦ y ≦ l and x + y ≦ 1. Alternatively, the layer sequence 7 can occur Phosphide compound semiconductors are based, ie it preferably contains Al _n Ga _{m In} min -mP / where O ≦ _n ≦ l, O ≦ _m ≦ l and n + m <1, preferably with n ≠ 0 and / or m ≠ 0 In this case, this material does not necessarily have to have a mathematically exact composition according to one of the above formulas. Rather, it may include one or more dopants as well as additional ingredients that do not substantially alter the physical properties of the material. For the sake of simplicity, the above formulas contain only the essential constituents of the crystal lattice (Al, In, Ga, N, P), although these may be partially replaced by small amounts of other substances.

The active zone of the layer sequence 7 emits when exposed to a current, for example electromagnetic radiation from the blue or ultraviolet wavelength range. It may, for example, have a pn junction, a double heterostructure, a single quantum well structure (SQW structure) or a multiple quantum well structure (MQW structure). Such structures are known to the person skilled in the art and are therefore not explained in detail at this point.

The LED chip 1 is connected by means of an electrically conductive connection means, e.g. a metallic solder or an adhesive, fixed with its rear side contact 2 on a first electrical connection 4. The front-side contact 3 is connected to a second connection 5 by means of a bonding wire 6.

The first and second terminals 4, 5 are embedded in a base housing 8 with a recess. In this case, the base housing 8 may be prefabricated. By "prefabricated" is meant that the base housing 8 is already finished on the terminals 4, 5, for example by means of injection molding, before the LED chip 1 is mounted on the first terminal 4. The base housing 8 consists for example of an opaque plastic and the recess is formed in terms of their shape as a reflector for the emitted from the LED chip 1 during operation radiation. Preferably, the reflector is formed by a reflective coating of the inner walls of the recess.

A first conversion layer 9 is applied directly to the radiation-emitting surface of the LED chip 1. This conversion layer 9 preferably contains silicone or a silicone-containing compound which contains a conversion element 10, preferably inorganic Conversion element, for white luminous components preferably Y ₃ Al ₅ Oi ₂ : Ce ³⁺ (YAG: Ce), are offset. Alternatively, the conversion layer 9 may comprise a ceramic compound or a transparent plastic, for example epoxy resin or polymethyl methacrylate, which with a conversion element 10, preferably inorganic conversion element, for white luminous components preferably Y ₃ Al ₅ O ₂ : Ce ³⁺ (YAG: Ce), are offset.

This first conversion layer 9 is surrounded by a further conversion layer 13 with conversion element 11 contained therein, preferably from an epoxy resin provided with the conversion element 11, particularly preferably with the conversion material used in the first conversion layer 9, which at least partially fills the recess. In this case, the concentration of the conversion element 11 of the second conversion layer 13 is lower than the concentration of the conversion element 10 of the first conversion layer 9.

The second conversion layer 13 may have one or more different conversion elements 11. As a conversion element, for example, inorganic conversion elements are suitable, such as with rare earths, in particular with Ce or Tb, doped garnets or organic conversion elements, such as perylene conversion elements. Further suitable conversion elements are listed, for example, in WO 98/12757 and in WO 01/65613 A1, the content of which is hereby incorporated by reference.

The illustrated in Figure 2 embodiment of an inventive device differs from the device in Figure 1, characterized in that the first Conversion layer 9 is applied over the entire surface of the radiation-emitting main surface of the LED chip 1, wherein the substrate of the LED chip 1 consists of a transparent material emitted by the LED chip during operation primary radiation. The recess in which the LED chip 1 is arranged has, by means of a reflective coating of the inner walls, a reflector 12 for the primary radiation emitted by the LED chip during operation.

In the case of the components illustrated in FIGS. 1 and 2, it is possible to arrange a beam-shaping element in the emission direction (not shown). It is advantageous if the second conversion layer 13 terminates with the base housing 8. This means that the second conversion layer 13 and the base housing 8 preferably have the same height. If the second conversion layer 13 does not terminate with the base housing 8, the distance, which results between the second conversion layer 13 and a beam-forming element, can be compensated by an adhesive, so that the conversion layer 13 with the adhesive disposed thereon and the base housing 8 have the same height.

By the beam-shaping element, the emission characteristics of the device can be advantageously influenced. For example, this element may be a lens.

Advantageously, in such a device, a comparatively small lens may be used as the beam-shaping element without significant dispersion effects. This is based on the fact that preferably the concentration of the conversion element 11 in the second Conversion layer 13 is less than the concentration of the conversion element 10 in the first conversion layer 9. Due to the low concentration of the conversion element 11 in the second conversion layer 13, a small number of scattering effects of the primary and secondary radiation takes place at the conversion elements 11 in the second conversion layer 13 , Thus, the emission surface of the radiation emitted by the LED chip 1 is advantageously essentially predetermined by the LED chip 1 and by the thin first conversion layer 9 applied to the surface of the LED chip 1.

The exemplary embodiments of FIGS. 1 and 2 have the advantage that due to the thin first conversion layer 9 applied to the surface of the LED chip, the path length through the first conversion layer 9 is approximately the same for the entire radiation emitted by the LED chip 1. The subsequent second conversion layer 13 contains a low concentration of conversion elements 11, resulting in the conversion element 11 of the second conversion layer 13 scattering effects of the primary and secondary radiation, resulting in an undirected scattered radiation of the primary and secondary radiation in all spatial directions. As a result, fluctuations of the color location over the emission angle can be reduced. A reduction of color inhomogeneities over the emission angle results with advantage.

Preferably, at least a portion of the secondary radiation of the second conversion element 11 has the same wavelength as the secondary radiation of the first conversion element 10. This increases the proportion of secondary radiation in the wavelength range of the conversion element 10 of the first conversion layer 9. The color location of the device emitted radiation is thereby shifted in the direction of the secondary radiation.

During the production of the component, the color location of the mixed radiation emitted by the LED chip 1, consisting of primary radiation and secondary radiation, which would otherwise show too strongly the color location of the primary radiation, can be adjusted by the second conversion layer 13 with conversion element 11 contained in it Color location of the radiation emitted by the device is shifted in the direction of the color locus of the secondary radiation.

Another advantage of the above

Conversion layer arrangement results from the fact that the second conversion layer 13 may contain a further conversion element 11, preferably a red phosphor, so that from a white distribution 'in the CIE color space in the color temperature range of about 6000K, the mixed radiation of a warm white distribution, preferably in the CIE Color space is in the color temperature range of 6000K - 2000K, can be generated.

The explanation of the device according to the invention with reference to the embodiments described above is not to be regarded as limiting the invention to these. Rather, the invention encompasses any novel feature as well as any combination of features, including in particular any combination of features in the claims, even if this feature or combination itself is not explicitly stated in the claims or exemplary embodiments.

Claims

claims

1. Radiation-emitting component having an LED chip (1) emitting primary radiation having a wavelength λ ₀ , a first conversion layer (9) which is applied to at least one main surface of the LED chip (1) and the at least one conversion element (10 ) which converts at least a part of a primary radiation emitted by the LED chip (1) into secondary radiation, a second conversion layer (13) arranged downstream of the first conversion layer (9) and comprising at least one conversion element (11) comprising at least one part the primary radiation emitted by the LED chip (1) converts into a secondary radiation, at least part of the secondary radiation of the conversion element (10) of the first conversion layer (9), a part of the secondary radiation of the

Conversion element (11) of the second conversion layer (13) and a portion of the unconverted primary radiation superimposed on a mixed radiation.

2. The radiation-emitting component according to claim 1, wherein the first conversion layer (9) is thinner than the second conversion layer (13).

3. Radiation-emitting component according to one of the preceding claims, wherein the concentration of the conversion element (11) in the second conversion layer (13) is less than the concentration of the conversion element (10) in the first conversion layer (9).

4. Radiation-emitting component according to one of the preceding claims, wherein the LED chip (1) in a recess of a base housing (8) is arranged and the recess is at least partially filled by the second conversion layer (13).

5. Radiation-emitting component according to one of the preceding claims, wherein the component has a reflector (12), wherein the LED chip (1) and the downstream conversion layers (9, 13) at least partially within the reflector (12) are arranged.

6. Radiation-emitting component according to one of the preceding claims, wherein the conversion element (11) of the second

Conversion layer (13) converts a portion of the primary radiation into secondary radiation having a plurality of wavelength ranges in mutually different spectral portions.

7. Radiation-emitting component according to one of the preceding claims, wherein at least a part of the secondary radiation of the second conversion element (11) has the same wavelength as the secondary radiation of the first conversion element (10).

8. Radiation-emitting component according to one of the preceding claims, wherein it emits mixed-colored light in operation.

A radiation-emitting device according to claim 8, wherein the mixed-color light is white light.

10. Radiation-emitting component according to claim 9, wherein the second conversion layer contains at least one further conversion element (11).

11. Radiation-emitting component according to claim 10, wherein the further conversion element (11) is a red phosphor.

12. Radiation-emitting component according to one of the preceding claims, wherein the wavelength λ _{0 of} the primary radiation in the ultraviolet or blue spectral range.

A radiation-emitting device according to any one of the preceding claims, wherein the device comprises a nitride compound semiconductor or a phosphide compound semiconductor.

14. Radiation-emitting component according to one of the preceding claims, wherein the secondary radiation of the conversion element (10, 11) of the first and / or second conversion layer (9, 13) in the yellow or red spectral range.

15. Radiation-emitting component according to one of the preceding claims, wherein the second conversion layer (13) is arranged downstream of a beam-shaping element.