Arrangement and method for generating mixed light

The invention claimed is: 1. An arrangement for generating mixed light, comprising: a first device; a second device; and a third device, the first device having a first semiconductor chip for generating a first primary radiation in the blue spectral range and having a first conversion element for generating a first secondary radiation from the first primary radiation, wherein a first total radiation exiting the first device has a first chromaticity coordinate, which lies within a color quadrilateral having the corner points (0.300, 0.425), (0.308, 0.439), (0.388, 0.407) and (0.370, 0.390) or (0.322, 0.482), (0.330, 0.500), (0.384, 0.450) and (0.375, 0.432) or (0.335, 0.345), (0.335, 0.365), (0.355, 0.365) and (0.355, 0.345), the second device having a second semiconductor chip for generating a second primary radiation in the blue spectral range and having a second conversion element for generating a second secondary radiation from the second primary radiation, wherein a second total radiation exiting the second device has a second chromaticity coordinate, which lies within a color quadrilateral having the corner points (0.325, 0.225), (0.350, 0.225), (0.350, 0.275) and (0.325, 0.275) or (0.350, 0.325), (0.365, 0.325), (0.350, 0.340) and (0.365, 0.340) or (0.445, 0.309), (0.457, 0.318), (0.425, 0.325) and (0.439, 0.337), and the third device having a third semiconductor chip for generating a third primary radiation in the blue spectral range and having a third conversion element for generating a third secondary radiation from the third primary radiation, wherein a third total radiation exiting the third device has a third chromaticity coordinate, which lies within a color quadrilateral having the corner points (0.475, 0.400), (0.425, 0.400), (0.425, 0.440) and (0.475, 0.440) or (0.515, 0.420), (0.495, 0.420), (0.515, 0.450) and (0.495, 0.450) or (0.425, 0.465), (0.425, 0.475), (0.440, 0.475) and (0.440, 0.465). 2. The arrangement according to claim 1 , wherein the first conversion element includes a first luminescent material which is a doped aluminum gallium oxide, and/or wherein the second conversion element includes a second luminescent material which is doped silicon oxynitride, silicon nitride, aluminum gallium oxide, aluminum silicon nitride and/or chlorosilicate, and/or wherein the third conversion element includes a third luminescent material which is doped aluminum gallium oxide, aluminum silicon nitride and/or silicon nitride. 3. The arrangement according to claim 1 , wherein the first conversion element includes a first luminescent material which is a doped aluminum gallium oxide, wherein the second conversion element includes a second luminescent material which is doped silicon oxynitride, silicon nitride, aluminum gallium oxide, aluminum silicon nitride and/or chlorosilicate, wherein the third conversion element includes a third luminescent material, which is Sr(Sr,Ca)Si 2 Al 2 N 6 :Eu 2+ , wherein the first chromaticity coordinate lies in a color quadrilateral having the corner points (0.300, 0.425), (0.308, 0.439), (0.388, 0.407) and (0.370, 0.390) and/or (0.322, 0.482), (0.330, 0.500), (0.384, 0.450) and (0.375, 0.432) and/or (0.335, 0.345), (0.335, 0.365), (0.355, 0.365) and (0.355, 0.345), wherein the second chromaticity coordinate lies in a color quadrilateral having the corner points (0.325, 0.225), (0.350, 0.225), (0.350, 0.275) and (0.325, 0.275) and/or (0.350, 0.325), (0.365, 0.325), (0.350, 0.340) and (0.365, 0.340) and/or (0.445, 0.309), (0.457, 0.318), (0.425, 0.325) and (0.439, 0.337), and wherein the third chromaticity coordinate lies in a color quadrilateral having the corner points (0.475, 0.400), (0.425, 0.400), (0.425, 0.440) and (0.475, 0.440) and/or (0.515, 0.420), (0.495, 0.420), (0.515, 0.450) and (0.495, 0.450) and/or (0.425, 0.465), (0.425, 0.475), (0.440, 0.475) and (0.440, 0.465). 4. The arrangement according to claim 1 , which consists of the first, second and third device, wherein one device partially converts primary radiation into secondary radiation and two devices fully convert primary radiation into secondary radiation, or wherein two devices partially convert primary radiation into secondary radiation and one device fully converts primary radiation into secondary radiation. 5. The arrangement according to claim 1 , wherein the first, second and third devices are configured such that the generation of the respective primary radiation in each of the first, second and third devices can be independently controlled. 6. The arrangement according to claim 1 , which has an overall emission having an intensity consisting of the first, second and third total radiations, the intensity of which being constant in the wavelength range of 500 nm to 650 nm with a deviation of +/−40%. 7. The arrangement according to claim 1 , wherein the first, second and/or third chromaticity coordinate has a color saturation of less than or equal to 82%. 8. The arrangement according to claim 1 , wherein the first, second or third chromaticity coordinate has a color saturation of less than or equal to 50%. 9. The arrangement according to claim 1 , wherein the first, second and third devices are arranged in a housing, wherein a common lens is arranged in the beam path of the first, second and third total radiation, which lens is configured to mix the first, second and third total radiations. 10. The arrangement according to claim 1 , wherein the first, second and third devices are spaced apart from each other so that the first, second and third conversion elements do not contact each other. 11. The arrangement according to claim 1 , wherein the first conversion element having at least one first luminescent material fully converts the first primary radiation into a first secondary radiation, wherein the first luminescent material is selected from the following group and combinations thereof and has a chromaticity coordinate having the coordinates L x1 , L y1 , and wherein L x1 and L y1 are selected from the following ranges: Y 3 (Al 1−x Ga x ) 5 O 12 :Ce 3+ where 0<x<1 and 0.432≤L x1 ≤0.469 and 0.520≤L y1 ≤0.545, Y 3 (Al 1−x Ga x ) 5 O 12 :Ce 3+ where 0<x<1 and 0.453≤L x1 ≤0.469 and 0.532≤L y1 ≤0.520, and Lu 3 (Al 1−x Ga x ) 5 O 12 :Ce 3+ where 0<x<1 and 0.356≤L x1 ≤0.374 and 0.561≤L y1 ≤0.573. 12. The arrangement according to claim 1 , wherein the second conversion element having at least one second luminescent material fully converts the second primary radiation into a second secondary radiation, wherein the second luminescent material is selected from the following group and combinations thereof and has a chromaticity coordinate having the coordinates L x2 , L y2 , and wherein L x2 and L y2 are selected from the following ranges: Lu 3 (Al 1−x Ga x ) 5 O 12 :Ce 3+ where 0<x<1 and 0.356≤L x2 ≤0.374 and 0.561≤L y2 ≤0.573, (Ba 1−x Sr x )Si 2 O 2 N 2 :Eu 2+ where 0<x<1 and 0.428≤L x2 ≤0.431 and 0.555≤L y2 ≤0.553, CaAlSiN 3 :Eu 2+ where 0.663≤L x2 ≤0.675 and 0.323≤L y2 ≤0.333, Ca 8 Mg(SiO 4 ) 4 Cl 2 :Eu 2+ where 0.2000≤L x2 ≤0.210 and 0.630≤L y2 ≤0.640, (Ca 1−x−y Ba x Sr y ) 2 Si 5 N 8 :Eu 2+ where 0<x<1 and 0<y<1 and 0.608≤L x3 ≤0.639 and 0.360≤L y3 ≤0.390, and Sr(Sr a Ca 1−a )Si 2 Al 2 N 6 :Eu 2+ where 0.6<a≤0.98 and 0.600≤L 2 ≤0.630 and 0.370≤L y2 ≤0.400. 13. The arrangement according to claim 1 , wherein the third conversion element having at least one third luminescent material fully converts the third primary radiation into a third secondary radiation, wherein the third luminescent material is selected from the following group and combinations thereof and has a chromaticity coordinate having the coordinat