The invention is based on a conversion LED according to the preamble of claim 1. Conversion LEDs of said type are suitable in particular for general lighting.
A conversion LED which uses a calsine as the red luminescent substance is known from EP 1 696 016. A white LED is realized therewith using a blue LED and a yellow or green luminescent substance chosen from α sialon, Y2A15O12:Ce or (Y,Gd)2(Al,Ga)5O12:Ce.
EP-A 1 669 429 discloses a conversion LED which employs a blue chip together with special luminescent substance of the type (Sr,Ba)2Si5N8:Eu in order to produce a white LED, wherein LuAG:Ce as well as similar luminescent substances which are co-doped with Ce and Pr are also used as additional luminescent substances to improve color rendering.
The object of the present invention is to provide a conversion LED which is equipped with a high color rendering index, wherein the conversion LED in particular achieves a long useful service life.
This object is achieved by means of the characterizing features of claim 1.
Particularly advantageous embodiments are to be found in the dependent claims.
According to the invention a high-efficiency conversion LED is now provided. Not all luminescent substances are stable in LEDs that are operated at high currents, here in particular at least 250 mA, preferably at least 300 mA, known as high-power LEDs. This problem applies in particular to nitride or oxinitride luminescent substances such as the nitride silicate M2Si5N8:Eu. Many such luminescent substances, in particular nitrides of the M2Si5N8:D type with D as an activator, suffer significant conversion losses during operation in an LED. LEDs of this type lose up to 50% of their conversion efficiency over a short period of time (typically 1000 hours). This results in a marked instability of the chromaticity coordinate.
White LEDs are becoming increasingly important in general lighting applications. Demand is increasing in particular for warm white LEDs having low color temperatures, preferably in the 2900 to 3500 K range, in particular 2900 to 3100 K, and having a good color rendering index, in particular Ra is at least 93, preferably 96, and at the same time having high efficiency. Against the background of the imminent ban on less energy-efficient general-purpose incandescent lamps, alternative light sources having the best possible color rendering index (CRI) are steadily gaining in significance. Many consumers hold illuminating means having a light spectrum similar to that of incandescent lamps in high regard.
Popular commercially available warm white LEDs generally consist of a combination of a blue LED with yellow and red luminescent substances. The color rendering index is typically around 80 in most cases. As a rule, much better color rendering indices are achieved by adding further luminescent substances, though this has a negative impact on the processing, chromaticity coordinate stability and efficiencies. Furthermore, very long-wave blue LEDs (approx. 460 nm) are used in most cases to compensate for the blue-green gap in the spectrum. From the chip technology perspective it is, however, advantageous for reasons of efficiency to use LEDs having shorter chip wavelengths since these are significantly more efficient. Wavelengths (peaks) from 430 to 455 nm, in particular 435 to 445 nm are desirable.
The luminescent substances must fulfill a number of requirements: very high stability in respect of chemical influences, for example oxygen, humidity, interactions with encapsulation materials, as well as in respect of radiation. In order to ensure a stable chromaticity coordinate as the system temperature rises, there is additionally a need for luminescent substances having very low thermal quenching characteristics.
Prior art warm white LEDs having a very high CRI are usually realized through a combination consisting of a relatively long-wave LED comprising a blue-green, a green-yellow and a red luminescent substance. Both the use of long-wave LEDs and the use of three luminescent substances are unfavorable from the application viewpoint and from efficiency considerations.
The novel solution consists of the combination of a novel green garnet luminescent substance and a narrowband red nitridoaluminosilicate luminescent substance. Compared with conventional yellow (YAG) or green-yellow (YAGaG) garnets, the new green garnet luminescent substance has a strongly green-shifted emission, while at the same time the excitation optimum is strongly shifted toward short wavelengths.
The spectral properties of the above-described luminescent substance combination permit the implementation of warm white LEDs up to solutions for 2900 to 3100 K having an extremely high CRI of 96 to 98 with at the same time very good red rendering (R9=90 to 99) in conjunction with blue LED chips having a peak wavelength of 440 to 445 nm. Even when very short-wave chips (peak wavelength 435 nm) are used, very good 95 CRI points are still reached. The restriction to just two converting luminescent substances greatly simplifies the processing in the LED and has a positive effect on the chromaticity coordinate stability. The two luminescent substances of the novel solution exhibit very high stability in LED aging tests. Furthermore, both luminescent substances are characterized by a very low thermal quenching response.
The crucial advancement now consists in the achievement of a simultaneous improvement in multiple crucial properties from the application perspective, namely in respect of aging stability, efficiency, usable chip wavelength range and temperature stability of the luminescent substances. The difference between this new solution and the known prior art warm white solutions is:
Essential features of the invention in the form of a numbered list are:
The invention shall be explained in more detail below with reference to a number of exemplary embodiments. In the figures:
An example of a modified luminescent substance (Ca0.892Mg0.1Eu0.008) (Al0.99B0.01)Si1N3 (CIE x/y=0.657/0340) of the basic structure type “CaAlSiN3:Eu” is given in Table 3. Further modifications with slightly altered cation ratio or partial CaSr substitution possibly in combination with a partial O/N substitution—such as e.g. (Ca0.945Sr0.045Eu0.01)AlSi(N2.9O0.1)—are also possible.
The color rendering index of the warm white LED having the novel luminescent substance mixture according to the invention (LuAGaG plus deep-red CaAlSiN3) shows a small dependence on the exciting blue LED wavelength used. A shift in the peak wavelength by 9 nm produces a CRI loss (Ra8) of only 3 points in the color rendering index. Other typical mixtures lose 5 points already with a difference of 7 nm peak wavelength in the blue (see Table 1). In order then to reduce the CRI loss there to 1 point it is necessary to add a third luminescent substance, which has a negative impact on efficiency and color steering. The dependence of the color rendering index on saturated red in particular is also very severely reduced, as is made apparent by the discrete value for R9.
Tab. 1 shows for the last two samples that excellent CRI values, namely Ra8 is at least 94 and the red index R9, at least 90, are possible in the 435 nm to 445 nm peak wavelength range of the exciting LED at a color temperature von 3000 to 3100 K.
In particular the dependence of the color rendering index on saturated red is also very greatly reduced, as is made apparent by the discrete value for R9 (see
Surprisingly, the novel green LuAGaG garnet behaves in a significantly different manner to the comparative luminescent substances. It exhibits a strong green shift with declining excitation wavelength. The comparative luminescent substances remain roughly constant. The emission spectra of the three luminescent substances are shown in comparison in the range of excitation by means of a LED with peak wavelength between 430 and 470 nm that is relevant to LED applications. The curves in
The use of a lutetium garnet has a significantly positive impact overall on the color rendering index. Compared with yttrium garnets with similar luminescent substance emission wavelength, much higher color rendering index values Ra8 and R9 are obtained with LuAGaG (see Table 2). As a result of this and by virtue of the good excitability at short wavelengths it is possible for the first time to use high-efficiency shortwave blue LEDs for warm white conversion LEDs for a color temperature of 2900 to 3150 K.
A very high color rendering index is achieved with just two luminescent substances, despite shortwave blue LED in the 435 to 455 nm range. In this case the special tuning of the two chosen luminescent substances to each other is important. For example, the use of a red luminescent substance of the nitridosilicate type emitting at an even longer wavelength does not increase the CRI value or the value for the red rendering R9, but yields poorer values. The use of Y garnets does not lead to the sort of high values that can be realized with Lu garnet. Details of various mixtures can be found in Tab. 3. Gd is totally unsuitable as a principal component and should, like Tb or La, be added to the component A at best in small amounts up to 5 mol.-% for fine tuning. In contrast, a Y fraction of up to approx. 30%, preferably with a fraction of 10 to 25%, makes a good addition to Lu. The cause is the relatively similar ionic radius of Lu and Y. However, higher values of Y would shift the emission of the luminescent substance back into a range which would adversely affect the desired performance of the overall system.
3:1
9:1
444
444
2:1
444
2:1
In principle it is possible to use the luminescent substance mixture as a dispersion, as a thin film, etc. directly on the LED or else, as known per se, on a separate carrier positioned upstream of the LED.
In principle it is not precluded that the garnet according to the invention, in addition to having predominantly Lu as principal component, also includes fractions of Y as cation A. These should be in the range of up to 32% at maximum. Other cations such as Tb, La, etc. are not categorically ruled out as additives, but due to their lack of conformance with the system (Lu, Y) should only be used in small amounts, preferably max. 5% of A, for any special-purpose adaptations of the properties of the luminescent substance.
Suitable modified calsines are shown in Tab. 4. This relates to systems that originate from the basic system CaAlSiN3:Eu. In this case the elements O, F, Cl can replace a percentage of the N, while the element Cu can replace a percentage of Ca.
All the starting materials are weighed out inside the glovebox and homogenized for six hours in a planetary mill. The mixture is loosely filled into a tightly closing crucible made of molybdenum and transferred to a high-temperature tubular furnace.
The annealing is carried out under a flowing nitrogen atmosphere (2 l/min). The sample is heated at a rate of 250 K/h to 1600° C., held at that temperature for four hours and cooled down to room temperature likewise at 250 K/h.
The resulting annealed cake is milled in a mortar mill and screened through a 30 μm gauze. The screened material is filled back into the crucible and annealed once more in a similar manner to the first annealing.
The resulting annealed cake is milled in a mortar mill and screened through a 30 μm gauze. The screened material is the luminescent substance S236.
The production of calsine as sample S176 is shown in Tab. 6.
All the starting materials are weighed out inside the glovebox and homogenized in a planetary mil for six hours 1. The mixture is loosely filled into a tightly closing crucible made of molybdenum and transferred to a high-temperature tubular furnace.
The annealing is carried out under a flowing nitrogen atmosphere. The sample is heated at a rate of 250 K/h to 1600° C., held at that temperature for four hours and cooled down to room temperature likewise at 250 K/h.
The resulting annealed cake is milled in a mortar mill and screened through a 30 μm gauze. The screened material is filled back into the crucible and annealed once more in a similar manner to the first annealing.
The resulting annealed cake is milled in a mortar mill and screened through a 30 μm gauze. The screened material is the luminescent substance S176.
Tab. 7 shows various garnets from the A3B5O12:Ce system, where A is chosen from (Lu, Y). It is demonstrated here that good values can be achieved for A=Lu up to A=70% Lu, remainder Y. At the same time the ratio between Al and Ga must be chosen carefully for component B. The Ga fraction should be between 10 and 40 mol.-%, in particular 10 to 25%. Various A3B5O12:Ce (Lu,Y) garnets are shown in Tab. 7, the concentration of the activator Ce being 2% of A in each case and the chosen ratio is A=Lu,Y (the Lu fraction is specified, remainder is Y) and B=Al,Ga (the Ga fraction is specified, remainder is Al).
Tab. 4 shows pure LuAGAG luminescent substances with incremental increases in Ga percentage. These table values, as of the other tables also, basically relate always to a reference excitation at 460 nm.
Number | Date | Country | Kind |
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10 2009 037 730.1 | Aug 2009 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2010/061694 | 8/11/2010 | WO | 00 | 2/17/2012 |