EP3592826A2 - Luminophore mixtures for use in dynamic lighting systems - Google Patents

Abstract

The present invention relates to novel luminophore mixtures and to a light-emitting device which contains at least one of the novel luminophore mixtures. The luminophore mixtures can be used in luminophore-converted LEDs with a semiconductor emitting in the violet spectral range. The present invention further relates to a lighting system which may comprise the light-emitting devices according to the invention, and to a dynamic lighting system. Furthermore, a method for producing the luminophore mixtures according to the invention and their use in light-emitting devices for use in general lighting and/or in special lighting are object of the present invention.

Description

 Phosphor mixtures for use

 in dynamic lighting systems

Subject of the invention

The present invention relates to novel phosphor mixtures and a light emitting device, in particular a light emitting device with phosphor conversion, such as a pc-LED (phosphor conversion light emitting device) containing at least one novel phosphor mixture. The phosphor mixtures can be used in phosphor-converted LEDs with a semiconductor emitting in the violet spectral region. Furthermore, the present invention relates to a lighting system, which may include the light-emitting devices of the invention, as well as a

dynamic lighting system. The present invention additionally relates to a process for the preparation of the phosphor mixtures according to the invention and to their use in light-emitting devices, in particular in US Pat

Light-emitting diodes (LEDs) for use in general lighting and / or in special lighting, for the conversion of blue, violet and / or

ultraviolet radiation in light of longer wavelength. The phosphor mixtures according to the invention are particularly suitable for use in dynamic lighting systems for generating white or colored light spectra with special properties, such as different levels of activation of melatonin synthesis in the human body in white light spectra or dynamic adaptation to different levels of chlorophyll absorption Special lighting systems for the

 Plant breeding.

Background of the Invention The meanwhile increasing role of LEDs in general lighting, but also in special lighting applications, has hitherto mainly been based on higher energy efficiency compared to conventional lighting techniques. In addition to the variability of the spectral composition by the principle of phosphor conversion, in particular for the production of white light, increasingly gaining other aspects, such as

Color quality, in particular color location, color temperature and color reproduction, on Significance that can only be achieved to a very limited extent with conventional light sources, if at all. A big advantage of LED based

Lighting technology is also in principle unrestricted

Combination ability of different light sources with different spectral distributions of the emitted light in a lamp to a lighting system, so that dynamic lighting systems, which can change their color temperature or other parameters coupled with the light spectrum, depending on the time, can be realized. Examples of such dynamic lighting systems are disclosed in patent publications US 2004/0105264 Al, EP 1 886 708 Al, WO 2012/033750 Al and DE 10 2013 208 905

AI shown.

US 2004/0105264 A1 relates to a method and apparatus having a multiple light source illumination device, the design and construction of which are derived from the lighting requirements of the specific application. The resulting illumination device allows illumination in accordance with the principles of proper lighting practice for optimum performance of visual tasks in the most efficient and cost effective manner. The coupling with sensors and logic control allows the illumination intensity and spectrum to be changed according to the changing needs of the user.

In EP 1 886 708 AI a lamp with "melatonin-friendly" effect is presented, which is based on a method for controlling a lamp, with the light can be generated in different spectral compositions, wherein the control of the spectral composition of the generated

Light is selected depending on a given time scheme.

WO 2012/033750 AI relates to light emitting diode (LED) light sources and

in particular an LED-based light source with decorative lighting function. Claimed is a light source system comprising several

Light emitting diode (LED) LEDs, wherein at least one LED source is configured to deliver an associated light output having an associated color of each of a plurality of colors; and a controller for selectively powering the LED sources for generating an alternating pattern of the associated light outputs and a corresponding alternating pattern of light is configured, which is delivered with the multiple colors and is visible to an observer.

DE 10 2013 208 905 A1 describes a concept for providing biologically optimized light and this concept underlying scientific

Findings. There will be a corresponding lighting system and

Lighting method provided with which a biologically optimized lighting situation can be produced in a local area, which is characterized by at least one specific characteristic.

The use of LEDs as light sources in lighting systems allows the principle unrestricted ability to combine the most diverse basic spectra together in one luminaire in order to realize dynamically adapted light spectra over time. Due to the laws of additive color mixing, for example, solid-color emitting semiconductor LEDs, which do not generate light

Phosphors (red-green-blue-violet) need to be interconnected to represent a large dynamic range of color temperatures or other spectral properties. A disadvantage of such a configuration, due to the number of separately controllable channels, the complexity of the necessary control. This must be in the one listed here

Example, the meaningful combination of 4 separate light sources allow. In addition to the required control electronics, for example, corresponding supply lines must be provided in the lighting system for the individual channels, which in turn can have a negative effect on the minimum required installation space.

It is therefore desirable to minimize the number of required light channels for the respective dynamic lighting application. The hitherto mainly applied concept of light generation by means of

Phosphor conversion is based on a blue-emitting semiconductor diode whose blue high-energy light in a phosphor layer containing fluorescent phosphors, partially absorbed and in light of lower energy or

higher wavelength is converted. Common here are phosphors that emit green, yellow, orange and / or red light. The combination of these phosphors in the right proportions results in interaction with the unabsorbed residual blue light, the ability to create tailored light spectra with respect to the color location of the emitted light.

 The basis for this is the additive color mixing of the different light frequencies emitted by the semiconductor diode and the phosphors. By a

Changing the mixture composition of the individual phosphors present in the phosphor layer, the color location of the light emitted from the overall system can be adjusted within certain limits.

Popular phosphor systems which emit green, yellow or orange light, such as orthosilicates ((Sr, Ba) 2SiO ₄ : Eu ²⁺ , see EP 1 970 970 A2), can not only sufficiently from not only blue, but also violet light be stimulated to issue. Common red-emitting

Phosphors, such. For example, nitride-based systems see. WHERE

2010/074963 AI), on the other hand, in addition to blue light, violet and even green light can be stimulated.

In a common configuration, consisting of a blue

emissive semiconductor diode, a green emitting phosphor, which is excited by the blue light, and a red-emitting phosphor, which can be additionally excited by the green light of the green-emitting phosphor, this leads to the following problem: The red phosphor absorbs parts of the from the green phosphor emitted light due to the said excitability in the green region of the light spectrum. A similar problem arises when combining a violet-emitting semiconductor diode with a blue-emitting phosphor excited by the violet light and a green-emitting phosphor which is additionally excited by the blue light of the blue emitting phosphor. Again, the green phosphor absorbs parts of the blue light of the blue phosphor.

Due to this re-absorption effect, the three primary colors that result in white light in the end can not be adjusted completely independently in the LED. In the case of the configuration with the blue semiconductor LED, an increase in the red component in the spectrum by a correspondingly higher mass fraction of the red-emitting phosphor in the phosphor mixture simultaneously leads to a disproportionate reduction in the green light component resulting spectrum due to the re-absorption of the green light by the red phosphor. To compensate for this, therefore, the mass fraction of the green phosphor must be increased so that the resulting predetermined color location can be maintained. In the case of the configuration with the violet-emitting semiconductor LED, an increase in the green component in the spectrum due to a higher mass concentration of the green phosphor leads to a disproportionate reduction of the blue light component in the spectrum, which is compensated by a corresponding increase in the mass fraction of blue phosphor got to. However, the concomitant increase in the phosphor mass concentration in the phosphor layer reduces the conversion efficiency of the phosphor layer in both cases described, which leads to a reduction in the radiometric radiation power and thus to a lower brightness and thus reduced overall efficiency of the phosphor-converted LED.

The currently predominant use of a blue-emitting semiconductor in combination with two phosphors, usually a green and a red-emitting phosphor, results in a clearly determined color location of the light emitted from the phosphor converted LED, which depends only on the phosphor composition. That of the blue-emitting

Semiconductor emitted light is in this case an integral part of the light emitted from the phosphor converted LED light, without which would set a different color location. Due to the spectral emission profiles of the semiconductor and the

used phosphors, in addition to the unique color location and the spectral overall profile of the light emitted from the phosphor converted LED light is uniquely determined. The spectral overall profile in turn determines other characteristics of the emitted light, such. For example, the color rendering index. Due to the uniqueness of the color location and the related

Spectral profiles are also clearly given the characteristics coupled to the spectral profile.

Thus, it is not possible with the usual configuration described here to produce two different phosphor converted LEDs, both identical phosphors, the same color locations, the same color rendering properties and / or same color temperatures, but different, with the spectral

Emission profile coupled characteristics have.

Object of the invention

The object of the present invention is to provide phosphor mixtures which are used in a light-emitting device, preferably a phosphor-converted LED, which is equipped with a semiconductor emitting in the violet and / or ultraviolet spectral range, and which provides the flexibility and overall efficiency of the energy conversion

 (Conversion efficiency) of the device. This results in a higher radiometric radiation power and a higher brightness of the light-emitting device. Furthermore, it is an object of the present invention to provide phosphor mixtures in which the basic colors of the individual phosphors can be varied independently of each other by changing the respective mass fractions without changing the mass fraction of a phosphor due to the mutual influence of the respective absorption and emission behavior the remaining phosphors to a change in the emitted

Basic colors of the other phosphors and thus to a further change in the properties of the emitted light comes.

A further object of the invention is to provide phosphor mixtures which make it possible to produce various light-emitting devices, preferably LEDs, having the same color locus, color rendering index and / or same correlated color temperature, but differing in their spectral profiles and the particular characteristics associated therewith

Distinguish properties.

"Equal" in the context of this application means that

(1) in the case of the color locus, the amount of the difference in the x color coordinates of the color locations to be compared of the different light emitting devices in the CIE-1931 standard (2 ° standard observer) standard is <0.007; this also applies to the amount of the difference of the y color coordinates (valid in the same color system) of the color locus to be compared;

 (2) in the case of the general color rendering index Ra (determined according to CIE 13.3-1995), the relative difference of the general color rendering indices in the light emitting device comparison is <7%;

 (3) in the case of the correlated color temperature (in K), the relative difference of the correlated color temperatures compared to the light-emitting

 Devices is <10%;

(4) in the case of the melatonin suppression level K _m ei, v (determined according to DIN SPEC 5031-100) the relative difference of the melatonin suppression levels compared to the light emitting devices is <5%; and

 (5) in the case of other, not explicitly listed parameters, the relative difference of these parameters compared to the light-emitting

 Devices at <10%, preferably at <7%, more preferably at <5%.

Particular properties which are coupled to the spectral profile are, for example, the proportion and intensity of individual colors or color ranges in the spectrum. For example, light with different levels of blue is used in dynamic lighting systems for "human centric lighting" applications, where the biological light effect on humans is the focus of the lighting concept , which take into account different levels of chlorophyll absorption, can be used.

The present invention aims to provide such dynamic

Lighting systems, which are suitable for example for "human centric lighting" applications or for plant breeding.

It is a further object of the present invention to provide phosphor blends which enable production of dynamic lighting systems which are less complex in construction than the prior art systems. Finally, it is the object of the present invention to provide a light-emitting device with the phosphor mixture according to the invention

corresponding illumination system to provide a method for producing the phosphor mixtures according to the invention and their use in a light-emitting device for light conversion.

Description of the invention

Surprisingly, it has been found that the objects described above are achieved by phosphor mixtures which contain at least one phosphor which can be emitted in the green spectral range of visible light and excited in the violet and / or ultraviolet spectral range, and contain at least one further phosphor which is present either in the can be emitted in the blue spectral range of visible light and excited in the violet and / or ultraviolet spectral range, emitted in the cyan spectral range of visible light and excited in the blue, violet and / or ultraviolet spectral range, emitted orange spectral range of visible light and blue, violet and / or ultraviolet spectral range can be excited or emitted in the red spectral range of visible light and excited in the blue, violet and / or ultraviolet spectral range.

In addition, the inventors of the present invention have surprisingly found that the phosphor mixtures according to the invention are suitable for use as conversion material in light-emitting devices, in particular in LEDs, for general and special lighting applications where by combining individual light spectra consisting of the phosphor mixtures used resulting in white light of one or more particular correlated color temperatures or colored light composed of different wavelengths.

Depending on the application, the generated light spectra can furthermore have certain properties, such as: B. in the case of white light spectra different levels of activation of Melatoninsynthese in

human body or z. B. in the case of special lighting systems for the Plant breeding the dynamic adaptation to different levels of chlorophyll absorption.

The objects described above are achieved, in particular, by phosphor mixtures which comprise i.) One or more compounds (i) of the formula (1) or formula (2)

(Ba, Sr, Ca) 2-cM ¹ cMgi-dM ² dSi20 ₇ -ef ₊ dFeClf: Eu, lvln (formula (1)) with:

M ¹ = one or more alkali metal elements;

M ² = Zr and / or Hf;

 0 <c <0.3;

 0 <d <0.3;

 0 <e <0.3; and

 0 <f <0.3;

(Β3.5Γ ^ 3) ₃ - _ν - _γ Α _γ Μ \ - _θ Μ ² _θ Μ ³ _ν Ο ₀ - _θ -γΝ _{θ + ν} Χ _{χ + γ} : Ευ (formula (2)) with:

 A = Na and / or K;

M ¹ = B, Al, Ga, In, Tl and / or Sc;

M ² = Si and / or Ge;

M ³ = Y, Lu and / or La;

 X = F and / or Cl;

 0.65 <a <1.0;

 0 <y <0, l-a;

 10,667 <b <11,133;

 0 <e <5.0;

 0 <v <0, l-a;

 17.00 <c <17.35;

 0 <x <5.0;

 0.0583 <a / b <0.0938;

 0.0375 <a / c <0.0588; and

2-a + 3-b = 2-c + x, if v = 0; ii.) one or more compounds (ii) selected from the group of blue or cyan emitting phosphors consisting of

(Sr, Ba, Ca) ₃ MgSi20 ₈ : Eu ²⁺ ; (Sr, Ba) io (PO ₄ ) ₆ CI ₂ : Eu; BaMgAli ₀ Oi ₇ : Eu ²⁺ ;

Sr ₄ Ali ₄ 0 ₂₅ : Eu ²⁺ ; BaSi ₂ 0 ₂ N _2: Eu ^2+; Lu ₃ (Al, Ga) ₅ 0i ₂ : Ce ³⁺ ; LiCaPO ₄ : Eu ²⁺ and

Mixtures thereof; and / or iii.) one or more compounds (iii) selected from the group of orange or red emitting phosphors consisting of (Sr, Ba) ₃ SiO 2: Eu ²⁺ ; (lx) (Sr, Ca) AISiN ₃ -x (Si ₂ N ₂ O): Eu ²⁺ (where 0 <x <1); (Sr, Ca) AISiN ₃ : Eu ²⁺ ; (Cai _x Sr _x ) S: Eu ²⁺ (with 0 <x <1); SruAl ₃ N ₄ : Eu ²⁺ ; 3.5 MgO-0.5 MgF ₂ -Ge0 ₂ : Mn ⁴⁺ ;

K ₂ (Si, Ti) F ₆ : Mn ⁴⁺ ; (Ba, Sr, Ca) ₃ MgSi ₂ O ₈ : Eu ²⁺ , Mn ²⁺ ; Ba ₂ (Lu, Y, Gd) i-xTb _x (B0 ₃ ) ₂ Cl: Eu ^{2 + / 3 +} (where 0 <x <1); Ba ₂ Mg (B0 ₃ ) ₂ : Eu ²⁺ ; La ₂ O ₂ S: Eu ³⁺ ;

(Sr, Ca, Ba) ₂ Si ₅ N ₈ : Eu ²⁺ ; (Sr, Ca, Ba) ₂ Si ₅ -x Al x N ₈ -x O x: Eu ²⁺ (where 0 <x <3.0);

EAdEucE _e NfOx (where EA = Ca, Sr and / or Ba; E = Si and / or Ge; 0.80 <d <1.995; 0.005 <c <0.2; 4.0 <e <6.0; 5 , 0 <f <8.7, 0 <x <3.0, and 2-d + 2-c + 4-e = 3-f + 2-x); A ₂ -o, 5y-xEuxSi5N ₈ - _y O _y (where A = Ca, Sr and / or Ba; 0.005 <x <1.0 and 0.1 <y <3.0), in particular (Sr, Ba ) i, ₇₇ Euo, o ₈ Si5N ₇ , ₇ Oo, ₃ ; Ma ₂ -y (Ca, Sr, Ba) i- _x - _y Si5-zMe _z N _8: EuxCe _y (with Ma = Li, Na and / or K; Me = Hf ⁴⁺ and / or Zr ^4+;

0.0015 <x <0.20; 0 <y <0.15; and z <4.0) and mixtures thereof; characterized in that the condition (A) or (B) is satisfied: w (i) => 35 to <95% by weight,

 w (ii) => 0 to <5.0 wt% and

 w (iii) => 5.0 to <50% by weight; w (i) => 35 to <85% by weight,

 w (ii) => 5.0 to <65 wt% and

w (iii) => 0 to <45% by weight; wherein w (i) denotes the mass fraction (wt .-%) of the compound (i), w (ii) denotes the mass fraction (wt .-%) of the compound (ii) and w (iii) the mass fraction (wt .-% ) of the compound (iii), in each case based on the total mass of the phosphor mixture; with the proviso that comprising phosphor mixtures

31.7% by weight of Sr ₂ , 5euo, i2Cao, 38MgSi ₂ 08;

63.5% by weight Bai, 9Euo, iMgo, 95Zr ₀ , 50Si ₂ 07, o5; and

4.8% by weight of CaAISiN ₃ : Eu are excluded.

In addition, a method for producing the phosphor mixture according to the invention is provided, which comprises the following steps:

a) weighing a mass m (i) of the phosphor (i), a mass m (ii) of the phosphor (ii) and / or a mass m (iii) of the phosphor (iii); and b) mixing the masses of the phosphors (i), (ii) and / or (iii) weighed in step a).

The phosphor mixtures according to the invention can be used in one

light-emitting device for converting blue, violet and / or ultraviolet radiation into light having a longer wavelength.

In addition, the present invention provides a light-emitting device having at least one primary light source and at least one phosphor mixture according to the invention.

Furthermore, an illumination system is claimed that contains at least two light-emitting devices, preferably LEDs, wherein the at least two light-emitting devices emit light with the same color location and / or color rendering index and / or the same correlated color temperature and wherein the light of the at least two light-emitting devices differs from the spectral composition, characterized in that each of the at least two light-emitting devices at least two different Phosphors, at least one of the phosphors being excitable by violet light and optionally by ultraviolet light and at 450 nm having a relative excitability of <65%, preferably <60%, more preferably <55%, more preferably <40%, and most preferably <30%, and wherein the maximum excitability in the excitation spectrum corresponds to 100%.

In addition, a dynamic lighting system is claimed, which contains two of the light emitting devices according to the invention, wherein the light emitting devices emitting light with the same color location and / or the same color rendering index and / or the same correlated color temperature, characterized in that the light of the light emitting devices with respect to the spectral composition different from each other.

At least one of the phosphors present in the phosphor mixtures,

light-emitting devices and illumination systems is not reabsorbing, which means that this phosphor is in the violet spectral range (400 to 430 nm) and optionally in the ultraviolet spectral range (100 to 399 nm) and / or partially in the blue spectral range (431 to about 449 nm) can be excited to emit light, but does not appreciably absorb light in the spectral region of> 450 nm, which means that at 450 nm the relative excitability is <65%, preferably <60%, more preferably <55%, more preferably <40% and most preferably <30%, wherein the maximum excitability in the excitation spectrum corresponds to 100%. This spectral range (> 450 nm) includes partially blue, cyan, green, yellow, orange and red light. For this reason, the mass fraction of at least one component of the phosphor mixture can be varied independently of the mass fractions of the other constituents, without it being due to the mutual influence of the respective absorption and

Emission behavior of the other phosphors comes to a change in the emitted primary colors of the other phosphors and the properties of the emitted light change further. This will increase the flexibility and

Overall system efficiency improved.

Figures 2 and 3 show excitation spectra of the compounds (i) which are used as non-reabsorbing phosphors in the phosphor mixtures according to the invention. The relative excitability of a phosphor can be determined from the excitation spectrum as follows: The maximum value of the excitation spectrum is set to 100% as a reference value, all other values, which are generally lower than or equal to the maximum value, are then calculated as a percentage of the maximum value and according to the wavelength of the

Excitation light applied. From the resulting graph, the relative excitability of the phosphor can be determined at the particular wavelength considered.

In the context of this application, ultraviolet light is defined as light whose emission maximum is between 100 and 399 nm, as violet light denotes light whose emission maximum is between 400 and 430 nm, blue light denotes such light, whose emission maximum is between 431 and 480 nm, as cyan light, whose emission maximum lies between 481 and 510 nm, as green light, that of

Emission maximum between 511 and 565 nm, as yellow light such, whose emission maximum is between 566 and 575 nm, such as orange light whose emission maximum is between 576 and 600 nm and as red light such, whose emission maximum is between 601 and 750 nm.

The phosphors, which are used as further constituents in the inventive

Fluorescent mixtures are used, can be well excited in the violet spectral range for light emission. Due to the laws of additive color mixing, three primary colors are always unique

 Determination of a color location necessary. In the case of using a blue-emitting semiconductor in combination with two phosphors, the light of the blue semiconductor LED is one of these primary colors. When using violet-excitable phosphors in the phosphor mixture in combination with a violet-emitting semiconductor, which emits a phosphor in the blue spectral range, there is now an interchangeability between the blue portion of the blue-emitting phosphor and the violet portion of the semiconductor in the resulting light the fluorescent converted LED.

As a result, the Farbort- and thus the Spektralprofileindeutigkeit are repealed, because the short-wave base color in the additive color mixing can now either from the blue-emitting phosphor or from the violet-emitting semiconductor or be a mixture of both proportions. As a result, it is now possible, with the same phosphors of different proportions, to produce different LEDs with an identical color location, but different spectral profiles, which consequently differ in their individual characteristics

Have spectral profile coupled characteristics.

"Human Centric Lighting" is the generic term biological

Light effects on the human body, the human being in the

Focus on the lighting concept of general lighting. A partial aspect of this is, for example, the activation (the wakefulness) by light. This is closely related to the content of the hormone melatonin in the human body. Melatonin acts as a synchronization transmitter for the inner clock of the human being to adapt this inner clock to the light-dark rhythm of the daylight. The information about the light gets over certain

 Photoreceptors in the eye to the inner, endogenous pacemaker, leading to

Suppression of melatonin synthesis in the body leads. Conversely, at lower ambient light intensities or darkness melatonin synthesis is not suppressed, whereby melatonin is transported through the bloodstream in all body cells and thus provides the information for synchronization.

The melatonin suppression has a spectral response curve, with the help of which in principle the level of melatonin suppression of a given light spectrum can be calculated. The spectral efficiency curve and the corresponding formulas are described in detail in DIN SPEC 5031-100 of August 2015.

The spectrum or color temperature of natural daylight generally changes over the course of a day. At noon, with high illuminance, daylight has a comparatively high color temperature, thus a comparatively high proportion in the blue region of the spectrum, while at dusk or at sunrise or sunset the natural light has a low color temperature and thus a comparatively low color temperature Blue portion has. Investigations have shown that the blue portion of the light the

Distribution of melatonin in general can suppress much more than the red portion of the light at the same intensity. In Figure 1 this is

Dependency shown in more detail. With the curve "C" is the empirically determined action spectrum for the suppression of melatonin, ie

"Melatonin suppression" indicated. The square symbols represent corresponding data according to Thapan, 2001, the data corresponding to triangular symbols according to Brainard, 2001. For comparison, the sensitivity of the human eye for night vision (curve "V") and daytime vision (curve "V") is also shown in the diagram. located. One recognizes for the

 Melatoninunterdrückung a wavelength maximum in the range of about 480 nm, more precisely to Brainard 464 nm and to Thapan 468 nm, ie in the blue region of the spectrum, and a significant decrease between about 520 nm and 560 nm. Radiation with wavelengths greater than about 560th nm therefore has very little potential to suppress melatonin release.

In general, when a person is exposed to artificial light at night, there is a possibility that the melatonin secretion of that human is adversely affected by the artificial light, in particular inhibited, so that the melatonin release into the blood in that human is correspondingly reduced.

As a consequence, undesirable effects, such as a reduction in sleep quality or even a weakening of the immune system can not be ruled out. It can be expected that the more intense the light is, the more pronounced is the undesired effect

Melatonin suppression increases with increasing brightness. Furthermore, it can be assumed that the longer the person is exposed to the light at night, the greater the undesired effect.

The above-described concept of the present invention makes it possible, by varying the composition of the phosphor mixture in the

light-emitting devices to produce light spectra, which have at otherwise the same correlated color temperature and thus the same color location, different levels of melatonin suppression. This variation of

Composition can be effected, for example, by varying the mass fraction of at least one component (phosphor) of the phosphor mixture. Corresponding LED spectra are shown in FIGS. 4 to 6. When realizing the white light spectra by means of a blue emitting

Semiconductor LED and corresponding conversion phosphors can be achieved in the Reg no identical color loci with such widely varying spectra, which have a marked difference in the level of melatonin suppression, because the light of the blue semiconductor LED in this case is always an integral part of the entire, from of the phosphor converted LED is light emitted. Dynamic lighting systems, such as "Human Centric Lighting" -

Lighting systems can, for example, change the spectral profile of the light emitted from the luminaires, depending on the time of day, in order, for example, to adapt the correlated color temperature to natural daylight.

More complex dynamic lighting systems, such as those known by Vossloh-Schwabe, are able to correlate with the correlated ones

Color temperature also to vary the level of melatonin suppression of the emitted spectra without other characteristic parameters associated with the spectral profile, such as the general

Color rendering index, also forced to vary. This is achieved by a complex structure via the addition of 4 basic spectra

(Vossloh-Schwabe, press kit Light + Building 2016, p. 20), which must be suitably combined with each other. The basic spectra can consist of monochromatic pure semiconductor LEDs as well as of phosphor-converted LEDs.

A clear advantage of the illumination system according to the invention compared to similar concepts is based on the fact that, for example, with only two light channels, each consisting of a white light spectrum and both having a nearly identical color location, with simple additive combination realizes a continuous shift in the level of melatonin suppression can change without changing the color location. This significantly reduces the complexity of a dynamic realized thereby

Lighting system. In addition to this advantage is in addition to call the reliability, because even if one of the light emission channels fails, the emitted light of the remaining channel still has a common white point and can be used for general lighting. In a complex multi-channel system, which uses, inter alia, monochromatic emitting LEDs, this advantage is no longer given.

Preferred embodiments are described in the dependent claims.

Description of the figures

FIG. 1: Diagram for suppression of melatonin release in FIG

 Dependence of the wavelength of the light falling on the retina. Figure 2: Excitation spectrum of Ba1.90Euo.10Mgo.95Zro.05Si2O7.05 at an emission of 517 nm.

 Figure 3: Excitation spectra of Bao.63075Euo.12Al O17.25Fo.0015 (solid line), Bao.63075Euo.12AI10.8Sco.2O17.25Fo.0015 (dashed line) and

 Bao.85575Euo.12AI10.85Sio.15O17.25No.15Fo.0015 (dotted line) with an emission of 521 nm.

 FIG. 4: Light emission spectra of LED examples 1 and 2.

 FIG. 5: light emission spectra of LED examples 3 and 4.

 FIG. 6: Light emission spectra of LED examples 5 and 6. Definitions

As used in the present application, the terms "phosphor" or "conversion phosphor", which are used herein as synonyms, refer to a particulate fluorescent inorganic material having one or more emissive centers. The emitting centers are formed by activators, usually atoms or ions of one

Rare earth element such as La, Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb and Lu, and / or atoms or ions of a transition metal element such as Cr , Mn, Fe, Co, Ni, Cu, Ag, Au and Zn, and / or atoms or ions of a main group metal element, such as Na, Tl,

Sn, Pb, Sb and Bi. Examples of phosphors or conversion phosphors include garnet-based phosphors, silicate-based phosphors,

Orthosilicate, thiogallate, sulfide and nitride based. Phosphor materials in the sense of the present invention have no ouanten- limiting effects. Such non-quantum limited phosphor materials may be phosphor particles with or without a silicon dioxide coating. Under a phosphor or conversion luminescent material in the sense of the present invention

Application is understood as meaning a material which absorbs radiation in a certain wavelength range of the electromagnetic spectrum, preferably in the blue, violet or ultraviolet spectral range, and visible in another wavelength range of the electromagnetic spectrum, preferably in the red, orange, yellow, green, cyan or blue spectral range Emitted light. In this context, the term "radiation-induced emission efficiency" is to be understood, i. H. The conversion phosphor absorbs radiation in a certain wavelength range and emits radiation in another wavelength range with a certain efficiency.

The term "emission wavelength shift" is understood to mean that one conversion phosphor is compared to another or similar

Conversion luminescent light emits light at a different wavelength, that is shifted to a smaller or larger wavelength.

The phosphor mixture according to the invention can be present as bulk material, powder material, thick or thin layer material or self-supporting material in the form of a film. Furthermore, it may be embedded in a potting material. The individual phosphors in the phosphor mixture may include adjunct materials, such as one or more coating materials.

The term "potting material" refers to a translucent

Matrix material, which includes the phosphor mixtures according to the invention. The translucent matrix material may be a silicone, a polymer (formed from a liquid or semi-solid precursor material such as a monomer)

Epoxy, a glass or a hybrid of a silicone and epoxy. Specific but non-limiting examples of the polymers include fluorinated ones

Polymers, polyacrylamide polymers, polyacrylic acid polymers, polyacrylonitrile polymers, polyaniline polymers, polybenzophenone polymers, poly (methyl methacrylate) polymers, silicone polymers, aluminum polymers, polybisphenol

Polymers, polybutadiene polymers, polydimethylsiloxane polymers, polyethylene polymers, polyisobutylene polymers, polypropylene polymers, polystyrene polymers, polyvinyl polymers, polyvinyl butyral polymers or perfluorocyclobutyl polymers. Silicones can gels such as Dow Corning ^® OE-6450, elastomers such as Dow Corning ^® OE-6520, Dow Corning ^® OE-6550, Dow Corning ^® OE

6630, and resins such as Dow Corning ^® OE-6635, Dow Corning ^® OE 6665, Nusil LS-6143 and other Nusil products, Momentive RTV615,

Momentive RTV656 and many other products from other manufacturers, including. Further, the potting material may be a (poly) silazane, such as

for example, a modified organic polysilazane (MOPS) or a

Perhydropolysilazane (PHPS), or a (poly) siloxazane. It is preferred that the proportion of the phosphor mixture, based on the potting material, in the range of 3 to 80 wt .-% is.

The term "coating material" refers to a material that has a

Coating forms on the surface of a phosphor particle. The term

"Coating" is used herein to describe one or more layers of material provided on another material that partially or wholly covers the outer surface or solvent accessible surface of the other material at least partially in the internal structure of the

Phosphor, which has been coated penetrate, provided that the coating as a barrier nor sufficient protection against external physical influences or the passage of potentially harmful substances, such. B.

Oxygen, moisture and / or free radicals. As a result, the stability of the phosphor is increased, resulting in improved durability and

Lifespan leads. Additionally, in some embodiments, the

Coating material provides the phosphor with additional functionality, such as reduced sensitivity to heat, reduced

Refraction or improved adhesion of the phosphor material in polymers or potting materials. Furthermore, bumps on the

Surface of the particles of the phosphor can be smoothed by the application of one or more coating materials. Such surface smoothing enables good processability of phosphor and reduces unwanted optical scattering effects of the emitted light on the surface of the material, resulting in increased efficiency.

Suitable materials for the coating are, in particular, metal oxides and nitrides, in particular earth metal oxides, such as Al 2 O 3, and earth metal nitrides, such as AlN, and also SiO 2. In this case, the coating can be carried out, for example, by fluidized bed processes or wet-chemical. Suitable coating methods are known, for example, from JP 04-304290, WO 91/10715, WO 99/27033, US 2007/0298250, WO 2009/065480 and WO 2010/075908. On the one hand, the aim of the coating can be a higher stability of the phosphors, for example against air or moisture. The aim can also be an improved coupling and decoupling of light by a suitable choice of the surface of the coating and the refractive indices of the coating material.

Preferred embodiments of the invention

Fluorescent mixture

The present invention relates to a phosphor mixture comprising one or more compounds (i) of formula (1) or formula (2), one or more compounds (ii) selected from the group of blue and cyan emitting phosphors, and / or a or a plurality of compounds (iii) selected from the group of orange or red emitting phosphors as defined in claim 1. The phosphor mixture according to the invention thus comprises one or more compounds (i) and at least one or more further compounds which are selected from the compounds (ii) and (iii). Thus possible are phosphor mixtures which comprise one or more compounds (i) and one or more compounds (ii); Phosphor blends comprising one or more compounds (i) and one or more compounds (iii); and phosphor mixtures comprising one or more compounds (i) and one or more compounds (ii) and one or more compounds (iii).

The compounds of formula (1) are pyrosilicate phosphors, which are known from WO 2016/173692 AI. The compounds of formula (2) are

Alkaline earth aluminate phosphors, which are known from WO 2016/150547 AI. The disclosure of WO 2016/173692 A1 and the disclosure of WO 2016/150547 A1 are hereby incorporated by reference into the present patent application.

It goes without saying that the compounds (i) of the formula (1) or formula (2), as well as the corresponding preferred embodiments, are charge-neutral, ie, that the positive charges of the cationic elements of the grid and balance the negative charges of the anionic elements of the lattice.

In a preferred embodiment, the compound (i) of the formula (1) in the phosphor mixture according to the invention is represented by the formula (3):

Ba2-abc-xSraCabM CMGI ^1-d _y M ² dSi207-ef ₊ dFeCl _f: Eux, Mn _y (formula (3)) comprising:

M ¹ = Li, Na, K and / or Rb;

M ² = Zr and / or Hf;

 0 <a <1.999, more preferably 0 <a <1.0, most preferably 0 <a <0.4;

 0 <b <1.999, more preferably 0 <b <1.0, most preferably 0 <b <0.4;

 0 <c <0.3, more preferably 0 <c <0.2;

 0 <d <0.3, more preferably 0 <d <0.2;

 0 <e <0.3, more preferably 0 <e <0.2;

 0 <f <0.3, more preferably 0 <f <0.2;

 0.001 <x <0.3, more preferably 0.005 <x <0.2; and

 0 <y <0.3.

For compounds of the formula (3) with c * 0 which contain M ¹ , the following is preferably valid for the index c: 0.001 <c <0.3, more preferably 0.01 <c <0.2.

For compounds of formula (3) with d * 0 containing M ² , the following is preferably for the index d: 0.001 <d <0.2, more preferably 0.01 <d <0.1.

When the compound (i) of the formula (1) or (3) contains more than one of Ba, Sr and Ca, the ratio of Ba, Sr and Ca within the

given sum formula are freely adapted. It is preferable that the compound (i) of the formula (1) or (3) contains not more than one of Ba, Sr and Ca, preferably Ba or Sr.

When the compound (i) of the formula (1) contains more than one of the elements M ¹ , the ratio of the alkali metal elements within the given Molecular formula be adapted freely. When the compound (i) of the formula (3) contains more than one of the elements M ¹ , the ratio of Li, Na, K and Rb can be freely adjusted within the predetermined parameters. It is preferred that M ¹ in formula (1) and (3) is Na and / or K.

When the compound (i) of the formula (1) or (3) contains more than one of the elements M ² , the ratio of Zr and Hf can be freely adjusted within the given empirical formula. It is preferable that M ² in formula (1) and (3) is Zr.

When the compound (i) of the formula (1) or (3) contains more than one of the elements F and Cl, the ratio of F and Cl within the given molecular formula can be freely adjusted.

In a preferred embodiment, the preferences are as above

mentioned elements in the formula (1) or (3) simultaneously.

It is preferred that in formula (3): c = 0, e = 0 and f = 0. Preferably, in formula (3), d = 0. Preferably, in formula (3), y = 0. Preferably, in formula (3) b = 0. Preferably, in formula (3), M = Na and / or K. These preferred embodiments can be combined in any manner.

It is preferable that the compound (i) has the formula (1) or the formula (3)

contains at least one of the elements M, Zr, F and / or Cl.

Europium is incorporated as a dopant in the form of divalent Eu ²⁺ on the lattice site of Ba and replaces it.

The preferred embodiments of the elements and parameters of formula (1) or (3) may be combined in any manner.

The compounds of formula (1) or (3) can be excited by ultraviolet and / or violet light, preferably from about 370 to about 430 nm, and have emission maxima in the green spectral range of

preferably about 510 to about 520 nm, depending on the exact composition. Particularly preferred compounds (i) of the formula (3) are compounds of the formulas (3a) and (3b):

Ba2-ab-xSr _a CabMgi-d-yM ² dSi207: Eux, Mn _y (Formula (3a)) Ba2-abc-xSraCabM ¹ cMgi- _y Si207-e-f + dF _e Clf: Eux, Mn _y (Formula ( 3b)) with:

M ¹ = Na and / or K;

M ² = Zr and / or Hf

 0 <a <1.999, more preferably 0 <a <1.0;

 0 <b <1.999, more preferably 0 <b <1.0;

 0 <c <0.3, more preferably 0 <c <0.2;

 0 <d <0.3; more preferably 0 <d <0.2;

 (0 <e <0.3 and 0 <f <0.3) or (0 <e <0.3 and 0 <f <0.3);

 0.001 <x <0.3; and

 0 <y <0.3.

Particularly preferred in formula (3a) and / or (3b): 0 <a <0.6. Most preferably, in formula (3a) and / or (3b): a = 0. Particularly preferred in formula (3a) and / or (3b): 0 <b <0.6. Most preferred in formula (3a) and / or (3b) is: b = 0.

Particularly preferred compounds of the formula (3) are shown in the following Table 1.

Table 1: Particularly preferred compounds of the formula (3). In a preferred embodiment, the compound (i) of the formula (2) in the phosphor mixture of the invention is represented by the formula (4): (Ba 1 2) 2-Ca 1-dv-yEudAyM 1 -eM 2 M 2 O-e-yNe + vXx + y (formula (4)) with:

 A = Na and / or K;

M ¹ = B, Al, Ga, In, Tl and / or Sc;

M ² = Si and / or Ge;

M ³ = Y, Lu and / or La;

 X = F and / or Cl;

 0.65 <a <1.0, more preferably 0.70 <a <0.80;

 0 <d <1.0, more preferably 0.03 <d <0.25, most preferably 0.05 <d <0.20;

 0 <y <0.1-a, more preferably 0 <y <0.05-a, most preferably 0 <y <0.03-a;

 10,667 <b <11,133;

 0 <e <5.0, more preferably 0 <e <1.0, most preferably 0 <e <0.2;

 0 <v <0.1-a, more preferably v = 0;

 17.00 <c <17.35;

 0 <x <5.0;

 0.0583 <a / b <0.0938;

 0.0375 <a / c <0.0588; and

 2-a + 3-b = 2-c + x, if v = 0.

It is preferred that in formula (4): 0.0005 <x + y <1.0, more preferably 0.001 <x + y <0.1, most preferably 0.001 <x + y <0.05;

 0.70 <a <0.80;

 0 <e <0.50;

 0.03 <d <0.25;

 10.93 <b <11.067; and

17.20 <c <17.30. When the compound (i) of the formula (2) or (4) contains more than one of Ba, Sr and Ca, the ratio of Ba, Sr and Ca can be freely adjusted within the given empirical formula. In a preferred embodiment, the compound (i) of the formula (2) or (4) contains <10 atom%

Sr and / or Ca, more preferably <5 at% Sr and / or Ca, and most preferably <3 at% Sr and / or Ca, based on the total content of Ba, Sr and Ca. It is preferable that the compound (i) of the formula (2) or (4) contains not more than one of Ba, Sr and Ca, more preferably Ba or Sr.

When the compound (i) of the formula (2) or (4) contains more than one of the elements A, the ratio of Na and K can be within the given

Molecular formula be adapted freely. It is preferable that A in formula (2) and (4) is K.

When the compound (i) of the formula (2) or (4) contains more than one of the elements M ¹ , the ratio of B, Al, Ga, In, Tl and Sc within the

given sum formula are freely adapted. In a preferred embodiment, compound (i) of formula (2) or (4) contains <10 at% of elements B, Ga, In, Tl and / or Sc, more preferably <5 at% of elements B, Ga , In, Tl and / or Sc, and most preferably <3 atomic% of the elements B, Ga, In, Tl and / or Sc, based on the total content of all elements M ¹ . It is preferable that M ¹ in formula (2) and (4) is Al, Ga and / or Sc, more preferably Al.

When the compound (i) of the formula (2) or (4) contains more than one of the elements M ² , the ratio of Si and Ge may be within the given

Molecular formula be adapted freely. It is preferable that M ² in the formula (2) and (4) is Si. A trivalent element M ¹ and a divalent oxide anion O ^2- are replaced by a tetravalent element M ² and a trivalent nitride anion N ^{3 "} .

When the compound (i) of the formula (2) or (4) contains more than one of the elements M ³ , the ratio of Y, Lu and La can be freely adjusted within the given empirical formula. It is preferred that M ³ in formula (2) and (4) La is. The trivalent element M ³ replaces an alkaline earth metal element Ba, Sr and / or Ca. The charge is compensated by trivalent nitride anion N ^{3 "} .

When the compound (i) of the formula (2) or (4) contains more than one of the elements X, the ratio of F and Cl within the given

Molecular formula be adapted freely. It is preferable that X in formula (2) and (4) is F. It is either possible for a monovalent alkali metal A and a monovalent anion X to replace an alkaline earth metal Ba, Sr and / or Ca and a divalent oxide anion O ² and / or for the charge of the monovalent anion X to be replaced by a lower content of the alkaline earth metal Ba, Sr and / or Ca is compensated and / or that a part of the divalent oxide anions O ^{2- is} replaced by two monovalent anions X.

In a preferred embodiment, the preferences of the above-mentioned elements in the formula (2) or (4) are present simultaneously.

It is preferred that in formula (2) or (4): x * 0 or y * 0 or v * 0 or e * 0 if Ca and Sr are not present and M ¹ = AI. The preferred embodiments of the elements and parameters of formula (2) or (4) may be combined in any manner.

The abovementioned conditions for the ratio of a / b and a / c ensure that the compound is formed in the β-alumina phase and results from a β-alumina structure of composition Bao, 75AlnOi7.25, as by X-ray powder diffractometry was detected. The compounds of the formula (2) or (4) show a pure Bao, 75AlnOi7.25 structure of ß-Aluminum oxide, even if they contain alkali metals A or trivalent metals M ³ or halide anions X, or if they contain, for example, Sc ³⁺ or other trivalent cations instead of Al ³⁺ or with Si ⁴⁺ and N ^{3 "} instead of

Al ³⁺ and O ² have been modified ^". Europium is incorporated as a dopant in the form of divalent Eu ²⁺ in the lattice site of Ba and replaces it.

The compounds of formula (2) or (4) can be excited by ultraviolet and / or violet light, preferably from about 370 to about 430 nm, and have emission maxima in the green spectral range of preferably about 510 to about 520 nm, depending on the exact composition.

Particularly preferred compounds of formula (4) are shown in Table 2 below.

Table 2: Particularly preferred compounds of formula (4). In a particularly preferred embodiment, the compound (i) of the formula (4) in the phosphor mixture according to the invention is represented by the formula (4a):

(Bai-zSrz) ad-yEudK _y (Ali-wSCw) Boc-y F _{x + y} (formula (4a)), comprising:

 0 <z <0.1, more preferably 0 <z <0.05, even more preferably 0 <z <0.03, and most preferably z = 0;

 0 <w <0.1, more preferably 0 <w <0.05, still more preferably 0 <w <0.03, and most preferably w = 0; wherein the parameters a, b, c, d, x and y have the definitions described for the formula (4).

In a particularly preferred alternative embodiment, the compound (i) of the formula (4) in the phosphor mixture according to the invention is represented by the formula (4b):

(Bai-z Ca z) ad-yEudK _y (Ali-wSCw) Boc-y F _{x + y} (formula (4b)), comprising:

 0 <z <0.1, more preferably 0 <z <0.05, even more preferably 0 <z <0.03, and most preferably z = 0;

 0 <w <0.1, more preferably 0 <w <0.05, still more preferably 0 <w <0.03, and most preferably w = 0; wherein the parameters a, b, c, d, x and y have the definitions described for the formula (4).

In a very particularly preferred embodiment, the compound (i) of the formula (4) in the phosphor mixture according to the invention is represented by the formula (5):

Ba _a -d-yEudKyAlbOc-yFx _{+ y} (formula (5)), wherein the parameters a, b, c, d, x and y have the definitions described for the formula (4).

In a preferred embodiment of the present invention, in addition to the one or more compounds (i) of formula (1) or (2), the phosphor mixture contains one or more compounds (ii) selected from the group of blue and cyan emitting phosphors, and one or more compounds (iii) selected from the group of orange or red emitting phosphors.

Preferably, the phosphor mixture contains only one compound each (i) and (ii) and / or (iii).

In a particularly preferred embodiment of the present invention, the phosphor mixture consists of one or more compounds (i) of the formula (1) or (2) and one or more compounds (ii) selected from the group of blue and cyan emitting phosphors, and / or one or more compounds (iii) selected from the group of orange or red emitting phosphors.

I n a most preferred embodiment of the present invention

In the invention, the phosphor mixture consists of a compound (i) of the formula (1) or (2) and a compound (ii) selected from the group of blue and cyan emitting phosphors, and / or a compound (iii) selected from the group of orange or red emitting phosphors.

The compounds (ii) are selected from the group of blue or cyan emitting phosphors consisting of (Sr, Ba, Ca) 3 MgSi208: Eu ²⁺ ;

(Sr, Ba) io (PO ₄ ) ₆ CI ₂ : Eu; BaMgAli ₀ Oi ₇ : Eu ²⁺ ; Sr ₄ Ali ₄ 0 ₂₅ : Eu ²⁺ ; BaSi ₂ 0 ₂ N _2: Eu ^2+;

Lu 3 (Al, Ga) 50i ₂ : Ce ³⁺ ; LiCaPO ₄ : Eu ²⁺ and mixtures thereof.

The compounds (iii) are selected from the group of orange or red emitting phosphors consisting of (Sr, Ba) 3SiOs: Eu ²⁺ ;

(lx) (Sr, Ca) AISiN ₃ -x (Si ₂ N ₂ O): Eu ²⁺ (where 0 <x <1), in particular

(Sr, Ca) o, 89Alo, 89Sii, iiN ₂ , 890 ₀ , ii: Eu ²⁺ ; (Sr, Ca) AISiN ₃ : Eu ²⁺ ; (Cai _x Sr _x ) S: Eu ²⁺ (with 0 <x <1); SrLiAl ₃ N ₄ : Eu ²⁺ ; 3.5 MgO-0.5 MgF ₂ -Ge0 ₂ : Mn ⁴⁺ ; K ₂ (Si, Ti) F ₆ : Mn ⁴⁺ ;

(Ba, Sr, Ca) 3 MgSi20 ₈ : Eu ²⁺ , Mn ²⁺ ; Ba ₂ (Lu, Y, Gd) i -xTbx (B0 ₃ ) 2CI: Eu ^{2 + / 3 +} (where 0 <x <1); Ba ₂ Mg (B0 ₃ ) ₂ : Eu ²⁺ ; La ₂ O ₂ S: Eu ³⁺ ; (Sr, Ca, Ba) ₂ Si ₅ N ₈ : Eu ²⁺ ; (Sr, Ca, Ba) ₂ Si ₅ - _x Al _x N ₈ -x O _x : Eu ²⁺ (where 0 <x <3.0); EAdEu _c E _e NfO _x (where EA = Ca, Sr and / or Ba; E = Si and / or Ge; 0.80 <d <1.995; 0.005 <c <0.2; 4.0 <e <6). 0, 5.0 <f <8.7, 0 <x <3.0, and 2-d + 2-c + 4-e = 3-f + 2-x); A ₂ -o, 5y-xEuxSi5N8-yO _y (where A = Ca, Sr and / or Ba; 0.005 <x <1.0, and 0.1 <y <3.0), especially (Sr, Ba) i , 77Euo, o8SisN7,70o, 3; Ma ₂ -y (Ca, Sr, Ba) i- _x - _y Si ₅ -zMezN _8: EuxCe _y (with Ma = Li, Na and / or K; Me = Hf ⁴⁺ and / or Zr ⁴⁺ 0, 0015 <x <0.20, 0 <y <0.15, and z <4.0) and mixtures thereof.

In a preferred embodiment of the present invention, the conditions (A) and (B) of the phosphor mixture are defined as follows:

(A) w (i) => 40 to <95% by weight,

 w (ii) => 0 to <5.0 wt% and

 w (iii) => 5.0 to <50% by weight;

(B) w (i) => 35 to <85% by weight,

 w (ii) => 5.0 to <65 wt% and

 w (iii) => 3.5 to <45% by weight.

Preferred phosphor mixtures for the generation of light spectra with different melatonin suppression levels are listed in Table 3. Table 3 shows preferred phosphor blend compositions that produce light spectra with different levels of melatonin suppression in the particular color temperature ranges indicated when using violet-emitting LED semiconductors as the excitation light source.

Melatonin composition ranges suppression

Color level range

 temperature LSSI LS 2 LS 3 LS 4 mel, v

 range / weight% / weight / weight% weight% according to DIN SPEC

 5031-100

 2500 K

0-0.0005 70-95 0-5 0-20 5-30 <3500 K

 3500 K

0-0.0009 60-80 0-5 0-20 5-20 <4500 K

 4500 K-

0-0.001 35-95 0-5 0-15 5-15 7000 K

2500 K

0.0005 - 0.001 45-70 10-50 0-15 5-30 <3500 K

 3500 K

0.0009 - 0.002 40-80 5-50 0-10 0-20 <4500 K

 4500 K-

0.001-0.002 35-85 15-65 0-10 0-20 7000 K

 Table 3: Preferred phosphor blends with associated color temperature and melatonin suppression ranges. The following Table 4 gives the respective individual components

(Phosphor components LS) of the phosphor mixtures shown in Table 3.

description of

 connection

 Single component

 Compounds (i) of the formulas (1), (2), (3), (3a), (3b), (4),

LS 1

 (4a), (4b) and / or (5).

Compounds (ii): (Sr, Ba, Ca) ₃ MgSi20 ₈ : Eu ²⁺ ,

(Sr, Ba) io (PO ₄ ) ₆ CI ₂ : Eu, BaMgAli ₀ Oi ₇ : Eu ²⁺ , Sr ₄ Ali ₄ O ₂₅ : Eu ²⁺ ,

LS 2

BaSi ₂ 0 ₂ N _2: Eu ^2+, Lu ₃ (Al, Ga) ₅ 0i _2: Ce ³⁺ and / or

LiCaPO ₄ : Eu ²⁺ .

LS 3 compound (iii): (Sr, Ba) ₃ Si0 ₅ : Eu ²⁺ .

Compounds (iii): (Sr, Ca) o, 89Alo, 89Sii, iiN ₂ , 890 ₀ , ii: Eu ²⁺ , (Sr, Ca) AISiN ₃ : Eu ²⁺ , (Sr, Ba) i, ₇₇ Eu ₀ , o8Si ₅ N ₇ , ₇ Oo, ₃ , (Cai _x Sr _x ) S: Eu ²⁺ (where 0 <x <1), SruAl ₃ N ₄ : Eu ²⁺ ,

3.5 MgO-0.5 MgF ₂ -GeO ₂ : Mn ⁴⁺ , K ₂ (Si, Ti) F ₆ : Mn ⁴⁺ ,

 LS 4

(Ba, Sr, Ca) ₃ MgSi ₂ O ₈ : Eu ²⁺ , Mn ²⁺ ,

Ba ₂ (Lu, Y, Gd) i -xTbx (B0 ₃ ) ₂ Cl: Eu ^{2 + / 3 +} (where 0 <x <1),

Ba ₂ Mg (B0 ₃ ) ₂ : Eu ²⁺ , La ₂ O ₂ S: Eu ³⁺ , (Sr, Ca, Ba) ₂ Si ₅ N ₈ : Eu ²⁺ and / or (Sr, Ca, Ba) ₂ Si5-x Alx N8- _x O _x : Eu ²⁺ (where 0 <x <3.0).

Table 4: Individual components of the phosphor mixtures shown in Table 3.

The phosphor mixture according to the invention can be converted for use in light-emitting devices, in particular in LEDs, in any external forms, such as, for example, spherical particles, platelets and structured materials and ceramics. These forms will be

According to the invention, the term "shaped body" is used to summarize the preform. The shaped body is preferably a "phosphor body". Another object of the present invention is thus a molding containing the phosphors of the invention. The preparation and use of corresponding moldings is familiar to the person skilled in the art from numerous publications.

Ceramics contain, in addition to the phosphor mixtures according to the invention, matrix materials, for example silazane compounds, in particular polysilazanes or polysiloxazanes. Particularly preferred matrix materials are perhydropolysilazane (PHPS), Al ₂ O ₃ , Y ₃ Al ₅ O ₂ , SiO ₂ , Lu ₃ Al ₅ O ₂ , Al ₂ W ₃ O ₂ , Y ₂ W ₃ O ₂ , YAlW ₃ O 2, ZrW ₂ 0 ₈ , Al ₂ Mo ₃ Oi ₂ , Y ₂ Mo ₃ Oi ₂ , YAIMo ₃ Oi ₂ , ZrMo ₂ O ₈ , Al ₂ WMo ₂ Oi ₂ , Y ₂ WMO ₂ O 12, YAIWMO ₂ O 12, ZrWMoOs, Al 2MOW ₂ O 12, Y 2MOW ₂ O 12, YAIMOW ₂ O 12 or mixtures thereof. Also suitable matrix materials are magnesium-aluminum spinel, yttrium oxide, aluminum oxynitride, zinc sulfide, zirconium oxide, lithium iodide oxide, strontium chromate, magnesium oxide, beryllium oxide, yttria-zirconia, gallium arsenide, zinc selenide, magnesium fluoride, calcium fluoride, scandium oxide, lutetium oxide and gadolinium oxide.

In addition, the phosphor mixtures according to the invention can also be provided as so-called "phosphor in glass" applications (PIGs), as described, for example, in WO 2013/144777 A1.

Process for the preparation of the phosphor mixture

The method according to the invention for producing a phosphor mixture as described above comprises the following steps: a) weighing a mass m (i) of the phosphor (i), a mass m (ii) of the

Phosphor (ii) and / or a mass m (iii) of the phosphor (iii); and

b) mixing the masses of the phosphors (i), (ii) and / or (iii) weighed in step a).

It is preferred that the elimination of the masses m (i), m (ii) and / or m (iii) in step a) takes place successively. In a particular embodiment, the weighing can also be done simultaneously.

The mixing in step b) is preferably carried out by means of a planetary centrifugal mixer, a roller bank, an overhead mixer, a

Taumelmischers, a Rhönradmischers, a ball mill, a mortar mill or a fluid bed mixer. In this case, the mixing process can be carried out both in the wet state (that is, the masses to be mixed are converted into a suitable mixture before being mixed

Liquid, such as. As water or ethanol, given) as well as in the dry state.

The steps a) and b) are preferably carried out at room temperature, more preferably at 20 to 25 ° C. Light-emitting device

The light-emitting device according to the invention contains at least one primary light source and at least one phosphor mixture, as described above.

Preferably, the primary light source is either a semiconductor light emitting diode (SLED), a semiconductor laser diode (LD) or an organic

light emitting diode (OLED). In an alternative preferred embodiment, the primary light source of the light-emitting device may be a plasma or discharge source. Preferred are those primary light sources that emit light in the spectral range from about 385 to about 480 nm, more preferably from about 390 to about 450 nm, and most preferably from about 395 to 440 nm.

A semiconductor light emitting diode (SLED) that forms a first group of suitable primary light sources is a two-wire semiconductor light source. It is a p-n junction diode that emits light when activated. When an appropriate voltage is applied to the leads, electrons can recombine with electron holes within the device, releasing energy in the form of photons. This effect is called electroluminescence, and the color of the light (corresponding to the energy of the photon) is determined by the energy bandgap of the semiconductor. The structure and mode of operation of a SLED are known to the person skilled in the art.

In a preferred embodiment, the primary light source is a SLED that is a luminescent indium-aluminum-gallium nitride, preferably of the formula In.GajAlkN (where 0 <i, 0 <j, 0 <k and i + j + k = 1) or a luminescent arrangement based on ZnO, a transparent conducting oxide (TCO), ZnSe or SiC.

A semiconductor laser diode (LD), also known as an injection laser diode or ILD, is an electrically pumped semiconductor laser in which the active laser medium is formed by a pn junction of a semiconductor diode similar to that in an S-LED. Construction and operation of an LD are known in the art. The LD is the most widely used type of laser for many applications, such as for example, fiber optic communication, barcode readers, laser pointers, CD and DVD and BLURAY-DISC readers and recorders, or similar, laser printers,

Laser scanner and increasingly directed light sources, is produced. A third group of suitable primary light sources comprises so-called organic light-emitting diodes (OLEDs), in which the emitting

The electroluminescent layer is an organic compound film that emits light in response to an electric current. This layer of organic semiconductor is located between two electrodes. Typically, at least one of these electrodes is transparent. Structure and functionality of

OLEDs are known to the person skilled in the art.

It is preferable that the light emitting device is a light emitting diode (LED). lighting system

The lighting system according to the invention contains at least two

light-emitting devices, preferably LEDs, wherein the at least two light-emitting devices emit light having the same color location and / or color rendering index and / or the same correlated color temperature and wherein the light of the at least two light-emitting devices differs from each other in spectral composition, characterized in that each the at least two light-emitting devices contain at least two different phosphors, wherein at least one of the phosphors is excitable by violet light and optionally by ultraviolet light and at 450 nm a relative excitability of <65%, preferably <60%, more preferably <55%, stronger preferably <40%, and most preferably <30%, and wherein the maximum excitability in the excitation spectrum corresponds to 100%.

The light of the at least two light-emitting devices differs in terms of spectral composition when at least one parameter associated with the spectral emission profile, e.g. the color locus, the color rendering, the correlated color temperature or the

Melatonin suppression, the first light-emitting device different from the corresponding parameter of the second light emitting device.

"To be different" in this context means that

(1) in the case of the color locus, the amount of the difference in the x color coordinates of the color locations to be compared of the different light emitting devices in the CIE-1931 standard (2 ° standard observer) standard is> 0.007; this also applies to the amount of the difference of the y color coordinates (valid in the same color system) of the color locations to be compared;

 (2) in the case of the general color rendering index Ra (determined according to CIE 13.3-1995), the relative difference of the general color rendering indexes compared to the light emitting devices is> 7%;

 (3) in the case of the correlated color temperature (in K), the relative difference of the correlated color temperatures compared to the light-emitting

 Devices are> 10%;

 (4) in the case of the melatonin suppression level Kmei, v (determined according to DIN SPEC 5031-100), the relative difference of the melatonin suppression levels compared to the light-emitting devices is> 5%; and

 (5) in the case of other, not explicitly listed parameters, the relative difference of these parameters compared to the light-emitting

 Devices at> 10%, preferably> 7%, more preferably> 5%.

In a preferred embodiment of the present invention, the at least two light emitting devices in the lighting system are light emitting devices according to the invention as described above.

Preferably, the lighting system of the present invention is a dynamic lighting system.

Furthermore, the present invention relates to a dynamic lighting system comprising at least two light emitting devices according to the invention, wherein the at least two light emitting devices according to the invention emit light with the same color location and / or same color rendering index and / or the same correlated color temperature, characterized in that the light of at least two light emitting according to the invention

Devices differ in terms of spectral composition from each other.

The light of at least two light emitting according to the invention

Devices in the dynamic illumination system differ in terms of spectral composition when at least one parameter associated with the spectral emission profile, e.g. the color locus, the color rendering, the correlated color temperature or the

Melatonin suppression, the first light-emitting device according to the invention differs from the corresponding parameter of the second light-emitting device according to the invention, as further defined above.

use

The phosphor mixtures according to the invention can be used in one

light-emitting device for converting blue, violet and / or ultraviolet radiation into light having a longer wavelength.

The light-emitting device is preferably a light-emitting diode (LED) for use in general lighting and / or in special lighting.

If the phosphor mixtures according to the invention are used in small amounts, they already give good LED qualities. The LED quality is described with conventional parameters, such as the color rendering index, the correlated color temperature, the lumen equivalent or absolute lumen or the color location in CIE x and y coordinates.

The Color Rendering Index (CRI) is a unitary photometric quantity known to those skilled in the art that compares the color fidelity of an artificial light source to the color fidelity of given reference light sources (the reference light sources have a CRI of 100 and the exact definition of the CRI can be found in FIG CIE Publication 13.3-1995).

Correlated Color Temperature (CCT) is a photometric quantity known to those skilled in the art with the unit of Kelvin. The higher the Numerical value, the higher the blue component of the light and the colder the white light of an artificial radiation source appears to the viewer. The CCT follows the concept of the black light emitter, whose color temperature describes the so-called Planckian curve in the CIE diagram.

The lumen equivalent is a photometric quantity known to those skilled in the art with the unit Im / W, which describes how large the photometric luminous flux in lumens of a light source is at a certain radiometric radiation power with the unit Watt. The higher the lumen equivalent, the more efficient a light source is.

The lumen is a photometrical photometric quantity which is familiar to the person skilled in the art and describes the luminous flux of a light source, which is a measure of the total visible radiation emitted by a radiation source. The larger the luminous flux, the brighter the light source appears to the observer.

CIE x and CIE y represent the coordinates in the familiar CIE standard color diagram (in this case normal observer 1931), which describes the color of a light source.

All the variables listed above can be calculated from the emission spectra of the light source using methods known to those skilled in the art.

All variants of the invention described in this application can be combined with each other, unless the respective embodiments are mutually exclusive. In particular, starting from the teachings of this document in the context of routine optimization, it is an obvious process to combine just different variants described here in order to arrive at a concrete, particularly preferred embodiment. The following examples are intended to illustrate the present invention and in particular show that

Result of such exemplary combinations of the described

Variants of the invention. However, they are by no means to be considered limiting, but rather are intended to encourage generalization. All compounds or components used in the formulations are either known and commercially available or can be synthesized by known methods. The temperatures given in the examples apply always in ° C. It goes without saying that both in the

Description as well as in the examples the quantities used

Ingredients in the compositions always add up to a total of 100%. Percentages are always to be seen in the given context.

Examples

Examples of phosphor mixtures according to the invention General instructions for the construction and measurement of phosphor-converted LEDs

A mass of ITILSI (in g) as listed in the respective LED example

Phosphor component 1 is used together with mi_s2 (in g) of the phosphor component 2 listed in the respective LED example, mi_s3 (in g) of the phosphor component 3 listed in the respective LED example, and mi_s4 (in g) of the phosphor component listed in the respective LED example 4 weighed and homogeneously mixed in a planetary centrifugal mixer.

Subsequently, the mixture is mixed with an optically transparent binder (eg silicone) and mixed so that the phosphor concentration in the optically transparent binder is expressed by CLS (in% by weight). The resulting binder-phosphor mixture is applied by means of an automatic dispenser on the chip of a violet-emitting semiconductor LED and cured with heat.

The violet-emitting semiconductor LEDs used in the present examples for LED characterization have emission wavelengths in the range of 405 nm-415 nm and are operated at 350 mA current. The photometric characterization of the LED is done with a spectrometer of the

Fa. Instrument Systems - spectrometer CAS 140 and an associated integrating sphere ISP 250. The LED is characterized by the determination of the wavelength-dependent spectral power density. The spectrum thus obtained of the light emitted by the LED is used to calculate the color point coordinates CIE x and y, the correlated color temperature (CCT). and, if necessary, the brightness or the melanopic yield of the visible radiation K _m ei, _{v used in} accordance with DIN SPEC 5031-100.

Table 5 shows LED examples 1 and 2 of a cold-white emitting LED with non-reabsorbing blue and green phosphors or a reabsorbing green phosphor.

Table 5: LED examples 1 and 2 with phosphor mixtures containing non-reabsorbing or reabsorbing phosphor mixture components.

LED Examples 1 and 2 show a non-reabsorbing system as compared to a reabsorbing system where the improvement in overall efficiency can be shown. FIG. 4 shows the light emission spectra of LED examples 1 and 2.

Table 6 shows LED examples 3 and 4 of a neutral-white-emitting LED with a low melatonin suppression level and a high melatonin suppression level, respectively.

18 45

 /Gew.-%:

 CIE

 0.376 0.376

 (1931) x:

 CIE

 0.374 0.375

 (1931) y:

 CCT / K: 4113 4113

 Cmel 0,0008 0,0010

Table 6: LED examples 3 and 4 with phosphor mixtures with high or low melatonin suppression level.

The LED examples 3 and 4 show two LED spectra which have a different level of melatonin suppression at almost identical color location and which can therefore be combined with one another in a 2-channel illumination system in the manner shown here. FIG. 5 shows the light emission spectra of LED examples 3 and 4.

Table 7 shows LED examples 5 and 6 of a neutral white emitting LED having a low melatonin suppression level and a high melatonin suppression level, respectively.

LED Example 5 LED Example 6 neutral white emitting LED neutral white emitting low LED with high LED

 Melatonin suppression level Melatonin suppression level green emitting phosphor green emitting phosphor according to compound (i) of compound (i) of the

LS 1 composition composition

 Bao.63075EUo.l2AlnOl7.25-Fo.0015 Bao.63075EUo.l2AlnOl7.25-Fo.0015

(See Table 2, compound 8) (see Table 2, compound 8) blue-emitting phosphor according to compound (ii) of the

LS 2

Composition (Sr, Ba, Ca) ₃ MgSi ₂ O ₈ : Eu ²⁺ orange emitting orange emitting phosphor

Phosphor according to compound according to compound (iii) of

LS 3

 (iii) the composition composition

(Sr, Ba) ₃ Si0 _5: Eu ²⁺ (Sr, Ba) ₃ Si0 _5: Eu ²⁺ red emitting phosphor Red emitting phosphor

LS 4

according to compound (iii) that according to compound (iii) of

 Table 7: LED examples 5 and 6 with phosphor mixtures with high or low melatonin suppression level.

The LED examples 5 and 6 show two LED spectra which have a different level of melatonin suppression at almost identical color location and which can therefore be combined with one another in a 2-channel illumination system in the manner shown here. FIG. 6 shows the light emission spectra of LED examples 5 and 6.

Claims

claims

Phosphor mixture comprising: i.) One or more compounds (i) of the formula (1) or formula (2) (Ba 1) 2CaO 2 -cM 1 Mgi-dM 2 SizOy-ef ₊ dFeClfiE 2 Mn (formula (1)) :

M ¹ = one or more alkali metal elements;

M ² = Zr and / or Hf;

 0 <c <0.3;

 0 <d <0.3;

 0 <e <0.3; and

 0 <f <0.3;

(Ba, Sr, Ca) a V ^M VeM ² _e M ^ Oc-e- _y N _{e + v} X _{x + y} : Eu (formula (2)) with:

 A = Na and / or K;

M ¹ = B, Al, Ga, In, Tl and / or Sc;

M ² = Si and / or Ge;

M ³ = Y, Lu and / or La;

 X = F and / or Cl;

 0.65 <a <1.0;

 0 <y <0, l-a;

 10,667 <b <11,133;

 0 <e <5.0;

 0 <v <0, l-a;

 17.00 <c <17.35;

 0 <x <5.0;

 0.0583 <a / b <0.0938;

 0.0375 <a / c <0.0588; and

2-a + 3-b = 2-c + x, if v = 0; ii. ) one or more compounds (ii) selected from the group of blue or cyan emitting phosphors consisting of

(Sr, Ba, Ca) ₃ MgSi20 ₈ : Eu ²⁺ ; (Sr, Ba) io (PO ₄ ) ₆ CI ₂ : Eu; BaMgAli ₀ Oi ₇ : Eu ²⁺ ;

Sr ₄ Ali ₄ 0 ₂₅ : Eu ²⁺ ; BaSi ₂ 0 ₂ N _2: Eu ^2+; Lu ₃ (Al, Ga) ₅ 0i ₂ : Ce ³⁺ ; LiCaPO ₄ : Eu ²⁺ and

Mixtures thereof; and / or iii. ) One or more compounds (iii) selected from the group consisting of orange or red-emitting phosphors consisting of (Sr, Ba) ₃ SIOS: Eu ^2+; (lx) (Sr, Ca) AISiN ₃ -x (Si ₂ N ₂ O): Eu ²⁺ (where 0 <x <1); (Sr, Ca) AISiN ₃ : Eu ²⁺ ; (Cai _x Sr _x ) S: Eu ²⁺ (with 0 <x <1); SruAl ₃ N ₄ : Eu ²⁺ ; 3.5 MgO-0.5 MgF ₂ -Ge0 ₂ : Mn ⁴⁺ ;

K ₂ (Si, Ti) F ₆ : Mn ⁴⁺ ; (Ba, Sr, Ca) ₃ MgSi ₂ O ₈ : Eu ²⁺ , Mn ²⁺ ; Ba ₂ (Lu, Y, Gd) i-xTb _x (B0 ₃ ) ₂ Cl: Eu ^{2 + / 3 +} (where 0 <x <1); Ba ₂ Mg (B0 ₃ ) ₂ : Eu ²⁺ ; La ₂ O ₂ S: Eu ³⁺ ;

(Sr, Ca, Ba) ₂ Si ₅ N ₈ : Eu ²⁺ ; (Sr, Ca, Ba) ₂ Si ₅ -x Al x N ₈ -x O x: Eu ²⁺ (where 0 <x <3.0);

EAdEucE _e NfOx (where EA = Ca, Sr and / or Ba; E = Si and / or Ge; 0.80 <d <1.995; 0.005 <c <0.2; 4.0 <e <6.0; 5 , 0 <f <8.7, 0 <x <3.0, and 2-d + 2-c + 4-e = 3-f + 2-x); A ₂ -o, 5 _{x y} -xEu Si5N ₈ - _y O _y (where A = Ca, Sr and / or Ba; 0.005 <x <1.0 and 0.1 <y <3.0); Ma ₂ - _y (Ca, Sr, Ba) _y ix- Si5-zMezN _8: Eu _x Ce _y (with Ma = Li, Na and / or K; Me = Hf ⁴⁺ and / or Zr ^4+; 0.0015 <x <0.20, 0 <y <0.15, and z <4.0) and mixtures thereof; characterized in that the condition (A) or (B) is satisfied:

(A) w (i) => 35 to <95% by weight,

 w (ii) => 0 to <5.0 wt% and

 w (iii) => 5.0 to <50% by weight;

(B) w (i) => 35 to <85% by weight,

 w (ii) => 5.0 to <65 wt% and

w (iii) => 0 to <45% by weight; wherein w (i) denotes the mass fraction (wt .-%) of the compound (i), w (ii) denotes the mass fraction (wt .-%) of the compound (ii) and w (iii) the mass fraction (wt .-% ) of the compound (iii), in each case based on the total mass of the phosphor mixture; with the proviso that comprising phosphor mixtures

31.7% by weight of Sr ₂ , 5euo, i2Cao, 38MgSi ₂ 08;

63.5% by weight Bai, 9Euo, iMgo, 95Zr ₀ , o5Si ₂ 07, i

4.8% by weight of CaAISiN ₃ : Eu are excluded.

A phosphor mixture according to claim 1, characterized in that the compounds (i) of the formula (1) are represented by the formula (3):

Ba2-abc-xSraCabM ¹ cMgi-d- _y M ² dSi ₂ 07-ef ₊ dFeClf: Eux, M n _y (formula (3)) with:

M ¹ = Li, Na, K and / or Rb;

M ² = Zr and / or Hf;

 0 <a <1,999;

 0 <b <1,999;

 0 <c <0.3;

 0 <d <0.3;

 0 <e <0.3;

 0 <f <0.3;

 0.001 <x <0.3; and

 0 <y <0.3.

Phosphor mixture according to claim 2, characterized in that in formula (3) c = 0, e = 0 and f = 0.

A phosphor mixture according to claim 2 or 3, characterized in that d = 0 in formula (3).

5. phosphor mixture according to one or more of claims 2 to 4, characterized in that in formula (3) y = 0. Phosphor mixture according to one or more of claims 2 to 5, characterized in that in formula (3) b = 0.

A phosphor mixture according to claim 1, characterized in that the compounds (i) of the formula (2) are represented by the formula (4):

(Ba ^^ CaJa -d-v-yEudAyM ^ -eM ^ M ^ Oc-e-yNe + vXx + y (formula (4)) with:

 A = Na and / or K;

M ¹ = B, Al, Ga, In, Tl and / or Sc;

M ² = Si and / or Ge;

M ³ = Y, Lu and / or La;

 X = F and / or Cl;

 0.65 <a <1.0;

 0 <d <1.0;

 0 <y <0, l-a;

 10,667 <b <11,133;

 0 <e <5.0;

 0 <v <0, l-a;

 17.00 <c <17.35;

 0 <x <5.0;

 0.0583 <a / b <0.0938;

 0.0375 <a / c <0.0588; and

 2-a + 3-b = 2-c + x, if v = 0.

A phosphor mixture according to claim 7, characterized in that in formula (4):

0.0005 <x + y <1.0, preferably 0.001 <x + y <0.1, more preferably

0.001 <x + y <0.05;

 0.70 <a <0.80;

 0 <e <0.5;

 0.03 <d <0.25;

 10.93 <b <11.067; and

17.20 <c <17.30. A phosphor mixture according to one or more of claims 1 to 8, characterized in that it contains one or more compounds (ii) and one or more compounds (iii).

A phosphor mixture according to one or more of claims 1 to 9, characterized in that the conditions (A) and (B) are defined as follows:

(A) w (i) => 40 to <95% by weight,

 w (ii) => 0 to <5.0 wt% and

 w (iii) => 5.0 to <50% by weight;

(B) w (i) => 35 to <85% by weight,

 w (ii) => 5.0 to <65 wt% and

 w (iii) => 3.5 to <45% by weight.

Process for the preparation of a phosphor mixture according to one or more of claims 1 to 10, comprising the steps:

 a) weighing a mass m (i) of the phosphor (i), a mass m (ii) of the phosphor (ii) and / or a mass m (iii) of the phosphor (iii); and b) mixing the masses of the phosphors (i), (ii) and / or (iii) weighed in step a).

A light-emitting device comprising at least one primary light source and at least one phosphor mixture according to one or more of claims 1 to 10.

A light emitting device according to claim 12, characterized in that the primary light source is a semiconductor light emitting diode (SLED), a semiconductor laser diode (LD), an organic light emitting diode (OLED) or a plasma or discharge source.

14. Lighting system comprising at least two light-emitting

Devices, wherein the at least two light-emitting Vorrichtu light with the same color location and / or the same color rendering index and / or the same correlated color temperature, and wherein the light of the at least two light emitting devices differs from each other in spectral composition, characterized in that each of the at least two light emitting

 Contains at least two different phosphors, wherein at least one of the phosphors is excited by violet light and optionally by ultraviolet light and at 450 nm has a relative excitability of <65% and wherein the maximum excitability in the excitation spectrum corresponds to 100%.

15. Illumination system according to claim 14, wherein the at least two

 light emitting devices are light emitting devices according to claim 12 or 13. 16. Lighting system according to claim 14 or 15, characterized in that it is a dynamic lighting system.

17. A dynamic lighting system comprising at least two light-emitting devices according to claim 12 or 13, wherein the at least two light-emitting devices light with the same color location and / or the same color rendering index and / or more correlated

 Color temperature emit, characterized in that the light of the at least two light-emitting devices with respect to the spectral composition differ from each other.

18. Use of a phosphor mixture according to one or more of claims 1 to 10 in a light-emitting device for the conversion of blue, violet and / or ultraviolet radiation into light having a longer wavelength.

19. Use according to claim 18, wherein the light-emitting device is a light-emitting diode (LED) for use in general lighting and / or in special lighting.