EP3121513A1 - Led light - Google Patents

Abstract

The invention relates to an LED luminaire with a lighting unit, which has a plurality of LEDs (R, G, B), which are designed to emit light in the primary colors red and green and blue of a color system, and a control unit, which with the Lighting unit is coupled and configured to drive the LEDs so that they additively generate light of a desired spectrum, wherein the illumination unit has a orange fluorescent converted LED (O), which in particular emits primarily light in a blue spectral range, wherein the orange phosphor converted LED (O ) is provided with a phosphor or phosphor mixture, which or is formed to the primary emitted light in particular completely in light whose spectrum has at least wavelengths in the range of 570 to 610, in particular from 560 to 620 nm, preferably 550 to 640 nm to convert, wherein the LEDs (B, G, R, O) of the lighting unit of the Steueru ngseinheit be controlled via separate control channels.

Description

The present invention relates to an LED luminaire having a lighting unit, which has a plurality of LEDs, which are designed to emit light in the primary colors red and green and blue of a color system, and a control unit, which is coupled to the lighting unit and designed to drive the LEDs so that they additively generate light of a desired spectrum.

LED lights of the known type are for example from the EP 2 541 362 A2 are known and used in particular to illuminate usable areas and especially goods presentation areas with objects lying thereon. The objective here is to emphasize the body color of the object to be illuminated and thus to illuminate the object with appropriately designed white light, in which the color component of the body color to be emphasized is enhanced. In addition to LEDs for the three primary colors red, green and blue, the previously known luminaire has a white light LED. Furthermore, a sensor system is provided which detects a light spectrum reflected by the useful surface or objects lying on the useful surface. The light spectrum is then evaluated to determine a dominant color from the reflected light spectrum detected by the sensor. Subsequently, the light emitting diodes are driven to emphasize the at least one dominant color such that they emit a light spectrum of predetermined color temperature or color intensity, in which the proportion of the at least one dominant color is enhanced.

The known lights have proven in principle. However, there is a need for more advanced LED lights, which can produce white light spectra with particularly good color reproduction, which is particularly suitable for optimal product presentation.

It is therefore an object of the present invention to design an LED luminaire of the type mentioned at the outset in such a way that it is capable of producing white light spectra with a high general color rendering index of the light generated and at the same time producing colored objects with strongly saturating light spectra. In particular, a high general color index of the generated light> 90 is desired.

This object is achieved in an LED lamp of the type mentioned in that the lighting unit has an orange phosphor converted LED, which in particular primarily emits light in a blue spectral range, wherein the orange phosphor converted LED is provided with a phosphor or phosphor mixture, which or which is configured to convert the primarily emitted light in particular completely into light whose spectrum has at least wavelengths in the range from 570 to 610 nm, in particular from 560 to 620 nm, preferably 550 to 640 nm, the LEDs of the illumination unit of the control unit via separate control channels are controlled.

It has been found that a combination of LEDs, which are designed to emit light in the three basic colors red, green and blue of the color system with a phosphor converted LED, which is adapted to the primary emitted light in broadband light in one yellow and / or orange spectral range, is ideally suited to receive additively light, which is characterized by a white light spectrum with particularly good color rendering.

According to the invention LEDs are thus provided for light in at least four color areas, specifically one for the blue, one for the green, one for the red and one for the orange or yellow-orange area and they can be controlled separately via the control unit of the LED lamp to additively obtain a desired spectrum. The luminaire according to the invention is accordingly designed such that it is characterized by at least four color channels.

In one embodiment, the LED light according to the invention is characterized by exactly four color channels, one blue, one green, one orange or yellow-orange and one red.

In the case of the LED which generates light in an orange or yellow and yellow spectral range, the invention relates to a phosphor-converted LED. This means that the LED is provided with an orange or orange-yellow phosphor (mixture), which or which can convert the light emitted primarily by the LED, which is in particular blue light, into longer-wave light. According to the invention, a phosphor (mixture) is used, which allows a conversion into orange or orange and yellow light with a comparatively broadband spectrum. Specifically, the spectrum of the converted light at least wavelengths in the range of 570 to 610 nm, in particular from 560 to 620 nm, preferably 550 to 640 nm. The spectrum of the phosphor-converted orange or orange and yellow light is characterized in particular by an intensity peak which extends at least over one of the aforementioned wavelength ranges, preferably even over further wavelengths.

The orange phosphor converted LED is also characterized in particular by the fact that it emits primarily blue light. Alternatively, for example, it is also possible to use a primary ultraviolet emitting LED.

In an advantageous embodiment, the orange phosphor converted LED is designed as fully converted phosphor LED, that is, the LED is designed such that the primary emitted by this light by means of the vorgeshenen phosphor (mixture) s completely in long-wavelength broadband light in orange or orange and yellow spectral range is converted.

The LED lamp according to the invention can in principle be distinguished by only one LED for each of the four colors or by two or more LEDs per color.

According to one embodiment of the invention, it is provided that the phosphor or the phosphor mixture of the orange phosphor-converted LED is designed to completely light the primary emitted light, whose spectrum has a maximum intensity wavelength in the wavelength range between 570 and 620 nm, in particular between 580 and 600 nm, preferably between 590 and 600 nm.

The spectrum of the converted light is characterized in particular by a broadband intensity peak whose wavelength at which the intensity is highest in the aforementioned range.

A further embodiment of the LED luminaire according to the invention is characterized in that the illumination unit has a green phosphor-converted LED, which in particular emits primarily light in a blue spectral range, wherein the green phosphor-converted LED with a phosphor or phosphor mixture is provided, which is or is formed to the primary emitted light in particular completely in light whose spectrum has at least wavelengths in the range of 500 nm to 540 nm, in particular 490 to 550 nm, preferably 480 to 570 nm to convert.

According to this embodiment, the LED, or those LEDs which are designed to emit light in the primary color green, are formed (in each case) by a green phosphor-converted LED, which in particular emits primarily in the blue.

According to the invention, the green phosphor-converted LED is provided with a phosphor or a phosphor mixture by which the primary emitted light is in particular completely converted into light whose spectrum has wavelengths in the green spectral range. Concretely, a conversion into light with a spectrum is achieved by means of the phosphor or phosphor mixture, which has at least wavelengths in the range of 500 nm to 540 nm, in particular 490 nm to 550 nm, preferably 480 nm to 550 nm. The phosphor or the phosphor mixture is accordingly designed to allow a particularly broadband emission in the green spectral range. The spectrum of the phosphor-converted green light is characterized in particular by an intensity peak which extends at least over one of the aforementioned wavelength ranges, preferably even over further wavelengths.

It can be provided that the phosphor or the phosphor mixture of the green phosphor-converted LED is formed to the primary emitted light in particular completely in light whose spectrum has a wavelength of maximum intensity in the wavelength range between 490 and 530 nm, in particular between 500 and 530 nm, preferably between 510 and 520 nm to convert.

The phosphor used for the green phosphor-converted LED is characterized in particular by a broadband intensity peak. from, whose maximum is in the aforementioned range.

According to an advantageous embodiment, both the at least one green and the at least one orange phosphor-converted LED emit primarily light in the blue spectral range. They are then of identical construction, in particular with the exception of the respective phosphor or phosphor mixture. In other words, identical semiconductor LEDs are used for the primary emission, which are provided with different phosphors or phosphor mixtures for conversion into light of different colors.

In a development of the invention, it can further be provided that the illumination unit has a red phosphor-converted LED which in particular primarily emits light in the blue or green spectral range, wherein the red phosphor-converted LED is provided with a phosphor or phosphor mixture which is designed to the primary emitted light in particular completely in light whose spectrum has at least wavelengths in the range of 620 nm to 670 nm, in particular 610 to 680 nm, preferably 600 to 690 nm to convert. The spectrum of the phosphor-converted red light is characterized in particular by an intensity peak which extends at least over one of the aforementioned wavelength ranges, preferably even over further wavelengths. According to this embodiment, according to the invention, that LED or, according to the invention, those LEDs which are designed to emit light in the primary color red are likewise formed by a phosphor-converted LED or by phosphor-converted LEDs.

The phosphor or the phosphor mixture of the red phosphor-converted LED is designed in an advantageous embodiment to the primary emitted light in particular completely in light whose spectrum has a maximum intensity wavelength in the wavelength range between 630 and 670 nm, in particular between 640 and 660 nm, preferably between 645 and 655 nm to convert.

If at least one phosphor converted LED is also provided for the red light, this is in particular provided with a red phosphor which allows a conversion into light of a spectrum having a broadband intensity peak with a maximum intensity wavelength in the aforementioned range.

Furthermore, it can be provided that the red phosphor-converted LED primarily emits light in the blue spectral range, wherein in particular the red phosphor-converted LED with the exception of the phosphor or phosphor mixture is constructed identical to the green and / or orange phosphor-converted LED.

In a particularly advantageous embodiment, identically designed semiconductor LEDs are used for the LEDs for all four colors, in particular identically formed blue semiconductor LEDs, the LEDs for the green and orange and possibly the red light in each case provided with a corresponding phosphor or phosphor mixture is. The same use Among other things, LEDs offer the great advantage that different heat developments in the luminaire according to the invention are avoided, which may allow an increased service life. By using identical LEDs, the luminaire according to the invention is also characterized by a particularly simple structure and can be manufactured comparatively inexpensively.

The phosphor-converted LEDs are provided, for example, with the phosphor or phosphor mixture in that the substrate of the respective light-emitting diode is coated with the phosphor or the phosphor mixture, for example a suspension of a plurality of phosphors. The phosphor or phosphors may also be embedded in a carrier material, for example a matrix of plastic, glass, silicone or epoxy resin, with which the LEDs are respectively provided. Other known ways in which the LEDs can be provided with a phosphor (mixture) are also possible.

As an alternative to the fact that for the red spectral region a phosphor-converted LED or a plurality of phosphor-converted LEDs are used, it can be provided that the illumination unit has a red LED which primarily emits light in a red spectral range, in which case the red LED is in particular formed as light Spectrum with an intensity peak with a central wavelength in the wavelength range between 610 and 650 nm, in particular between 620 and 640 nm, preferably between 625 and 635 nm to emit, and wherein in particular the intensity peak of the red LED has a half-width of at least 15 nm, preferably at least 20 nm.

In a further development, it is then provided in particular that the illumination unit has a further red LED, which primarily contains light in another emitted red spectral region, wherein in particular the further red LED is adapted to emit light of a spectrum with an intensity peak with a central wavelength in the wavelength range 650-680 nm, in particular between 660 and 670 nm, and wherein in particular the intensity peak of the other red LED a Half width of at least 15 nm, preferably at least 20 nm. If one or more LEDs emitting primary red light are used instead of at least one phosphor-converted LED for the red spectral range, it is particularly expedient if one or more LEDs emitting primarily in a lower red wavelength range and one or more LEDs emitting primarily in a higher wavelength range LEDs are used.

According to this embodiment, instead of the phosphor-converted LED with a red phosphor, a semiconductor LED is used for the red spectral region, which emits primarily red light. In an advantageous embodiment, it is then provided in particular that, in addition to the red LED, another red LED is used which emits light with a spectrum which is distinguished by wavelengths other than the first red LED. In this way it is achieved according to the invention that a comparatively large spectral range in the red is also covered by the use of LEDs emitting primarily red. The LED lamp according to the invention is characterized according to this embodiment by at least 5 color channels, two color channels for the red area, specifically a red and a deep red color channel are provided.

According to a further embodiment of the LED luminaire according to the invention, a blue LED is used for the blue spectral range, which emits primarily light in a blue spectral range. It can be provided in particular that the blue LED is formed, light of a Spectrum with an intensity peak in the wavelength range between 430 and 470 nm, in particular between 440 and 465 nm, preferably between 450 and 455 nm to emit. In this case, it can then be further provided that the intensity peak of at least one blue LED has a half-width of at least 15 nm, preferably at least 20 nm.

In a further development, the illumination unit can also have a further blue LED, which primarily emits light in a blue spectral range, in which case the further blue LED is formed, light of a spectrum with an intensity peak with a central wavelength in the wavelength range between 450 and 480 nm, in particular between 465 and 475 nm, preferably between 465 and 470 nm, and in which, in particular, the intensity peak of the further blue LED has a half-width of at least 15 nm, preferably at least 20 nm.

Also for the blue spectral range, a semiconductor LED can be used according to the invention. In this case, in particular a further blue LED can be used which emits primarily in the deep blue spectral range.

If a blue and a further blue as well as a red and a further red LED are provided, the LED luminaire according to the invention is distinguished by at least six color channels.

Particularly advantageous is an embodiment with two different primary emitting in the blue LEDs, a green and an orange or orange-yellow phosphor converted LED and two different primary emitting red LEDs. The LED lamp according to the invention is then characterized by exactly six separately controllable color channels. In particular, one color channel in each case serves for the emission in the deep blue and in the blue, one color channel of the emission in the green and in the orange or orange and yellow, and two other channels of emission in red and deep red.

For the yellow, the green and possibly the red phosphor-converted LED is in principle any known phosphor or any known phosphor mixture, which is designed to convert the particular blue emitted primarily by an LED light into light whose spectrum is one of the aforementioned inventive Embodiments corresponds. The person skilled in the art knows which phosphor or which phosphor mixture is suitable in each case in order to achieve the corresponding light conversion.

In this case, the phosphor used is, for example, a phosphor or phosphor mixture, which enables the conversion of the primary emitted light into broadband light in the respective spectral range.

• Die vorgenannten Prozentzahlen können sich jeweils auf den maximalen Ansteuerungswert der Kanäle der vier unterschiedlichen Farben beziehen oder
• auf einen beliebigen anderen Wert. Wesentlich ist, dass die Gewichtung der vier Kanäle zueinander der Gewichtung der vorgenannten Prozentangaben entspricht.

Another embodiment is characterized in that the LEDs are driven to produce a white light spectrum at about 2700 K with very high color rendering. It is provided in particular that the control channels of the LEDs are controlled with the following percentages of a predetermined, in particular maximum activation value for the respective color: Blue LED: 25-35%, in particular 28-32%, preferably 29.88%, Green phosphor converted LED: 55-65%, in particular 60-64%, preferably 62.64%, orange fluorescent converted LED: 50-60%, in particular 52-56%, preferably 54.12%, red phosphor converted LED: 90-100%, especially 100%.

• The abovementioned percentages may each refer to the maximum drive value of the channels of the four different colors or
• to any other value. It is essential that the weighting of the four channels to one another corresponds to the weighting of the abovementioned percentages.

Alternatively, it can be provided that the LEDs are driven to produce a neutral white white light spectrum at about 4000 K with very high color rendering, in particular the control channels of the LEDs are controlled with the following percentages of a predetermined, in particular maximum activation value for the respective color: Blue LED: 90-100%, especially 100%, Green phosphor converted LED: 80-90%, in particular 82-98%, preferably 85.92%, orange fluorescent converted LED: 42-55%, in particular 45-50%, preferably 47.89%, red phosphor converted LED: 65-75%, in particular 68-72%, preferably 69.40%.

It can also be provided that the LEDs for generating a cold white white light spectrum at about 5500 K are driven with very high color rendering.

For this purpose, the control channels of the LEDs can be controlled in particular with the following percentages of a predetermined, preferably maximum activation value for the respective color: Blue LED: 90-100%, especially 100%, Green phosphor converted LED: 60-70%, in particular 62-65%, preferably 63.95%, orange fluorescent converted LED: 15-25%, in particular 18-22%, preferably 20.01%, red phosphor converted LED: 35-45%, especially 36-40%, preferably 38.26%.

As an alternative to the aforementioned activation values, the LEDs of the LED luminaire according to the invention can be driven to produce a warm white white light spectrum at about 2700 K with good color rendering to emphasize a red color. The control of the control channels of the LEDs is then carried out in particular with the following percentages of a predetermined, preferably maximum activation value for the respective color: Blue LED: 25-35%, in particular 26-30%, preferably 28.23%, Green phosphor converted LED: 50-60%, in particular 52-58%, preferably 54.33%, orange fluorescent converted LED: 30-40%, in particular 32-38%, preferably 35.83%, red phosphor converted LED: 90-100%, especially 100%.

Another alternative is that the LEDs are driven to produce a neutral white white light spectrum at around 4000K with good color rendering to accentuate a red color.

For this purpose, the control channels of the LEDs can be specifically controlled with the following percentages of a predetermined, in particular maximum activation value for the respective color: Blue LED: 88-98%, in particular 90-94%, preferably 92.80%, Green phosphor converted LED: 85-95%, in particular 89-94%, preferably 91.89%, orange fluorescent converted LED: 20-30%, in particular 24-29%, preferably 26.01%, red phosphor converted LED: 90-100%, especially 100%.

Does the LED lamp according to the invention at least one blue LED that emits primarily in a blue spectral range and at least one more blue LED that emits primarily in a wider blue spectral range, and at least one red LED that emits primarily in a red spectral region and at least one Another red LED, which emits primarily in a further red spectral range, can be provided that the LEDs are driven to produce a cold white white light spectrum at about 5500 K with good color rendering to emphasize a red body color. In particular, the control channels of the LEDs are controlled with the following percentages of a predetermined, in particular maximum activation value for the respective color: Blue LED: 18-28%, especially 20-25%, 23.09%, further blue LED: 8-18%, especially 10-15%, 13.48%, Green phosphor converted LED: 15-25%, in particular 19-24%, preferably 21.08%, orange fluorescent converted LED: 3-13%, in particular 6-11%, preferably 8.79%, red LED: 0-5%, especially 0%, another red LED: 90-100%, especially 100%.

Finally, if the LED luminaire according to the invention is distinguished by six color channels, that is, the lighting unit has a red and a further red LED and a blue and a further blue LED, it can be provided that the LEDs produce a warm white white light spectrum at about 2700 K. be driven with good color rendering to emphasize a red body color. The control of the control channels of the LEDs is carried out in particular with the following percentages of a predetermined, in particular maximum activation value for the respective color: Blue LED: 0-8%, especially 1-5%, 3.08%, further blue LED: 0-8%, especially 1-6%, 3.82%, Green phosphor converted LED: 5-15%, especially 5-10%, preferably 8.66%, orange fluorescent converted LED: 8-18%, in particular 10-15%, preferably 12.17%, red LED: 0-5%, especially 0%, another red LED: 90-100%, especially 100%.

Figur 1

ein Weißlichtspektrum bei etwa 2700 K mit sehr hoher Farbwiedergabe, das erfindungsgemäß mit einer 4-Kanal-LED-Leuchte gemäß der vorliegenden Erfindung erzeugt ist;

Figur 2

ein neutralweißes Weißlichtspektrum bei etwa 4000 K mit sehr hoher Farbwiedergabe, das erfindungsgemäß mit einer 4-Kanal-LED-Leuchte gemäß der vorliegenden Erfindung erzeugt ist;

Figur 3

ein kaltweißes Weißlichtspektrum bei etwa 5500 K mit sehr hoher Farbwiedergabe, das erfindungsgemäß mit einer zur 4-Kanal-LED-Leuchte gemäß der vorliegenden Erfindung erzeugt ist;

Figur 4

ein warmweißes Weißlichtspektrum bei 2700 K mit guter Farbwiedergabe zur Betonung einer roten Körperfarbe, das erfindungsgemäß mit einer 4-Kanal-LED-Leuchte gemäß der vorliegenden Erfindung erzeugt ist;

Figur 5

ein neutralweißes Weißlichtspektrum bei etwa 4000 K mit guter Farbwiedergabe zur Betonung einer roten Körperfarbe, das erfindungsgemäß mit einer zur 4-Kanal-LED-Leuchte gemäß der vorliegenden Erfindung erzeugt ist;

Figur 6

ein Vergleichsbeispiel eines kaltweißen Weißlichtspektrums bei etwa 5500 K zur Betonung einer roten Körperfarbe;

Figur 7

ein kaltweißes Weißlichtspektrum bei 5500 K mit guter Farbwiedergabe zur Betonung einer roten Körperfarbe, das erfindungsgemäß mit einer 6-Kanal-LED-Leuchte gemäß der vorliegenden Erfindung erzeugt ist, und

Figur 8

ein warmweißes Weißlichtspektrum bei 2700 K zur Betonung einer roten Körperfarbe, das erfindungsgemäß mit einer 6-Kanal-LED-Leuchte gemäß der vorliegenden Erfindung erzeugt ist.

The mode of operation of the LED luminaire according to the invention will now be described in more detail in two embodiments with reference to the drawings. In the drawing shows:

FIG. 1

a white light spectrum at about 2700 K with very high color rendering, which is produced according to the invention with a 4-channel LED lamp according to the present invention;

FIG. 2

a neutral white white light spectrum at about 4000 K with very high color rendering produced according to the invention with a 4-channel LED luminaire according to the present invention;

FIG. 3

a cool white white light spectrum at about 5500 K with very high color rendering, which is produced according to the invention with a 4-channel LED lamp according to the present invention;

FIG. 4

a warm white white light spectrum at 2700 K with good color rendering to emphasize a red body color produced according to the invention with a 4-channel LED lamp according to the present invention;

FIG. 5

a neutral white white light spectrum at about 4000 K with good color rendering to emphasize a red body color produced according to the invention with one to the 4-channel LED lamp according to the present invention;

FIG. 6

a comparative example of a cold white white light spectrum at about 5500 K to emphasize a red body color;

FIG. 7

a cool white white light spectrum at 5500 K with good color rendering to emphasize a red body color, which is produced according to the invention with a 6-channel LED lamp according to the present invention, and

FIG. 8

a warm white white light spectrum at 2700 K to emphasize a red body color, which according to the invention with a 6-channel LED lamp is produced according to the present invention.

A first embodiment of an LED lamp according to the present invention is implemented in 4-channel technology and comprises LED boards with a blue light emitting diode B, which emits primarily light in a blue spectral range, a green phosphor converted LED G, an orange phosphor converted LED O. and a red phosphor converted LED R. The spectra of the light generated by the four LEDs B, G, O, R are in the FIGS. 1 to 6 each shown.

In the illustrated embodiment of the LED lamp according to the invention, the blue light-emitting diode B is concretely designed to emit light of a spectrum with an intensity peak in the wavelength range between 450 nm and 455 nm. Specifically, the maximum of the intensity peak of the spectrum emitted by the blue LED is about 453 nm.

The green phosphor converted LED G is configured to emit primarily light in a blue spectral region and is provided with a phosphor which is configured to convert the primarily emitted blue light into light, the spectrum of which is spread over a comparatively wide wavelength range in the Greens stretches. Specifically, the spectrum of the light converted by the green phosphor converted LED G has an intensity peak having wavelengths in the range of about 430 nm to 720 nm, with the half width of the intensity peak extending from about 480 nm to 580 nm. The half-width of the peak is about 100 nm.

The spectrum of the light converted by means of the green phosphor-converted LED G is further characterized by a maximum intensity in the wavelength range between 510 nm and 520 nm, specifically a maximum intensity at about 515 nm.

The red phosphor converted LED R is provided with a phosphor mixture which is designed to completely convert the primarily emitted blue light into light whose spectrum has wavelengths in the range of 560 nm to more than 760 nm. Specifically, the converted light is characterized by an intensity peak whose maximum lies in the red spectral range between 645 nm and 655, specifically at about 648 nm. The half-width of the intensity peak of the red phosphor-converted LEDs is about 110 nm, is concretely about 605 nm to 715 nm.

Finally, the primary blue-emitting orange phosphor-converted LED O is also provided with a phosphor mixture which is designed to convert the primary light completely into light, the spectrum of which has wavelengths in the range from about 520 nm to 740 nm. Specifically, the converted light is characterized by an intensity peak whose maximum value in the wavelength range between about 590 nm and 600 nm, specifically at about 592 nm. The half-width of the intensity peak of the orange phosphor-converted LEDs is about 80 nm.

In the FIG. 1 a light emission spectrum E is shown, which is generated by driving the four LEDs B, G, OR, to obtain a white light spectrum at 2700 K with very high color rendering.

In the following Table 1, the weighting of the emission spectra of the four channels (that is, driving signals of the four LED channels for the four different colors) is shown to be in the example of FIG FIG. 1 mentioned properties to achieve according to the invention. A weighting of 1,0000 corresponds to the maximum activation of the respective channel, the other values are scaled linearly proportionally. Table 1: LED channel LED channel LED channel LED channel B G O R .2988 .6264 .5412 1.0000

Table 2, below, contains the colorimetric property that is compatible with the weighting factors from Table 1 for the example of FIG. 1 result. Table 2: parameter value statement CCT: 2750 Most similar color temperature, 2700K: warm white, 4000 K: neutral white; 5500 K: cool white Δu'v ': 0.00200 Distance from the Planckian curve (for warm white and neutral white) or from the curve of the daylight phases (for cold white), which describes the quality of the white. The quality is perceptually acceptable iA when Δu'v '≤ 0.002. R _a : 94 General color rendering index, the value of 90 corresponds to "good to very good" R _1-14 92.93 Average of the color rendering indices of the 14 test colors TCS01-TCS14; the value of 86 corresponds to "good to very good" C * _(red) 67.98 CIELAB chroma (a term similar to saturation), this value corresponds to the accentuation of red object colors. The higher the value, the more saturated the illuminated red objects. R ₉ 90.09 Special color rendering index for red object colors, the value of 90 corresponds to "good" color rendering for red objects

In the FIG. 2 is an emission spectrum E for producing a neutral white white light spectrum at 4000 K shown with very high color rendering, which is generated by driving the four LEDs B, G, OR.

Table 3, below, shows the weighting of the emission spectra of the four channels (that is, drive signals of the LED channels) to those in the example of FIG FIG. 2 mentioned properties to achieve according to the invention. A weight of 1.0000 corresponds to the maximum control of the respective channel, the other values are scaled linearly proportional. Table 3: LED channel LED channel LED channel LED channel B G O R 1.0000 .8592 .4789 .6940

The following Table 4 contains the colorimetric properties that are consistent with the weighting factors from Table 3 for the example of FIG. 2 result. Table 4: parameter value statement CCT: 4050 Most similar color temperature, 2700K: warm white, 4000 K: neutral white; 5500 K: cool white Δu'v ': 0.00200 Distance from the Planckian curve (for warm white and neutral white) or from the curve of the daylight phases (for cold white), which describes the quality of the white. The quality is perceptually acceptable iA when Δu'v '≤ 0.002. R _a : 98 General color rendering index, the value of 90 corresponds to "good to very good" R _1-14 96.21 Average of the color rendering indices of the 14 test colors TCS01-TCS14; the value of 86 corresponds to "good to very good" C * _(red ) 64,10 CIELAB chroma (a term similar to saturation), this value corresponds to the accentuation of red object colors. The higher the value, the more saturated the illuminated red objects. R ₉ 90.76 Special color rendering index for red object colors, the value of 90 corresponds to "good" color rendering for red objects

The FIG. 3 shows an emission spectrum E, which is a cool white white light spectrum at 5500 K with very high color rendering, which is generated by driving the four light emitting diodes B, G, OR.

Table 5 shows the weighting of the emission spectra of the four channels (ie drive signals of the LED channels) in order to achieve the properties mentioned in the example of FIG. 3 according to the invention. A weighting of 1.0000 again corresponds to the maximum control of the respective channel, the other values are scaled linearly proportional. Table 5: LED channel LED channel LED channel LED channel B G O R 1.0000 .6395 .2001 .3826

Table 6 contains the colorimetric properties that are consistent with the weighting factors from Table 5 for the example of FIG. 3 result. Table 6: parameter value statement CCT: 5505 Most similar color temperature, 2700K: warm white, 4000 K: neutral white; 5500 K: cool white Δu'v ': 0.00168 Distance from the Planckian curve (for warm white and neutral white) or from the curve of the daylight phases (for cold white), which describes the quality of the white. The quality is perceptually acceptable iA when Δu'v '≤ 0.002. R _a : 98 General color rendering index, the value of 90 corresponds to "good to very good" R _1-14 96.57 Mean value of special color rendering indices 14 test colors TCS01-TCS14; the value of 86 corresponds to "good to very good" C * _(red) 61.79 CIELAB chroma (a term similar to saturation), this value corresponds to the accentuation of red object colors. The higher the value, the more saturated the illuminated red objects. R ₉ 98.54 Special color rendering index for red object colors, the value of 90 corresponds to "good" color rendering for red objects

In the FIG. 4 is a warm white white light spectrum at 2700 K with good color rendering (R _a = 90) to emphasize a red body color shown.

Table 7 shows the weighting of the emission spectra of the four channels (ie drive signals of the LED channels) in order to achieve the properties mentioned in the example of FIG. 4 according to the invention. A weight of 1.000 corresponds to the maximum control of the respective channel, the other values are linearly scaled. Table 7: LED channel LED channel LED channel LED channel B G O R .2823 .5433 .3583 1.0000

Table 8 contains the colorimetric properties that are consistent with the weighting factors of Table 7 for the example of FIG. 4 result. Table 8: Colorimetric properties of the example of FIG. 4. parameter value statement CCT: 2705 Most similar color temperature, 2700K: warm white, 4000 K: neutral white; 5500 K: cool white Δu'v ': 0.00200 Distance from the Planckian curve (for warm white and neutral white) or from the curve of the daylight phases (for cold white), which describes the quality of the white. The quality is perceptually acceptable iA when Δu'v '≤ 0.002. R _a : 90 General color rendering index, the value of 90 corresponds to "good to very good" R _1-14 87.31 Average of the color rendering indices of the 14 test colors TCS01-TCS14; the value of 86 corresponds to "good to very good" C * _(red ) 70.57 CIELAB chroma (a term similar to saturation), this value corresponds to the accentuation of red object colors. The higher the value, the more saturated the illuminated red objects. R ₉ 84.99 Special color rendering index for red object colors, the value of 90 corresponds to "good" color rendering for red objects

The FIG. 5 also shows an emission spectrum E for a neutral white white light spectrum at 4000 K with good color rendering (R _a = 90) to emphasize a red body color.

Table 9 shows the weighting of the emission spectra of the four channels (ie drive signals of the LED channels) shown in the example of FIG FIG. 5 mentioned properties to achieve according to the invention. A weight of 1.0000 corresponds to the maximum control of the respective channel, the other values are scaled linearly proportional. Table 9: LED channel LED channel LED channel LED channel B G O R .9280 .9189 .2601 1.0000

Table 10 contains the colorimetric properties that are consistent with the weighting factors from Table 9 for the example of FIG. 5 result. Table 10: Colorimetric properties of the example of FIG. 5. parameter value statement CCT: 4005 Most similar color temperature, 2700K: warm white, 4000 K: neutral white; 5500 K: cool white Δu'v ': 0.00200 Distance from the Planckian curve (for warm white and neutral white) or from the curve of the daylight phases (for cold white), which describes the quality of the white. The quality is perceptually acceptable iA when Δu'v '≤ 0.002. R _a : 90 General color rendering index, the value of 90 corresponds to "good to very good"" R _1-14 87.07 Average of the color rendering indices of the 14 test colors TCS01-TCS14; the value of 86 corresponds to "good to very good" C * _(red ) 68.89 CIELAB chroma (a term similar to saturation), this value corresponds to the accentuation of red object colors. The higher the value, the more saturated the illuminated red objects. R ₉ 60.36 Special color rendering index for red object colors, the value of 90 corresponds to "good" color rendering for red objects

In the FIG. 6 For example, a comparative example is shown which includes the emission spectrum E of a cold white white light spectrum at 5500 K with a color rendition of only R _a = 82 and a non-excellent white point to emphasize a red body color.

Table 11 shows the weighting of the emission spectra of the four channels (ie drive signals of the LED channels), in the example of FIG FIG. 6 to achieve the emission spectrum shown. A weight of 1.0000 corresponds to the maximum control of the respective channel, the other values are scaled linearly proportional. Table 11: LED channel LED channel LED channel LED channel B G O R 1.0000 .6584 0.0000 .6723

As is apparent from Table 11, the weighting of the orange LED channel, which according to the invention using an orange realized in this example, 0.0000, ie, the orange phosphor converted LED has no light emitted.

Table 12 contains the colorimetric properties that are consistent with the weighting factors from Table 11 for the example of FIG. 6 result. Table 12: Colorimetric properties of the example of FIG. 6. parameter value statement CCT: 5505 Most similar color temperature, 2700K: warm white, 4000 K: neutral white; 5500 K: cool white Δu'v ': 0.00500 Distance from the Planckian curve (for warm white and neutral white) or from the curve of the daylight phases (for cold white), which describes the quality of the white. The quality is perceptually acceptable iA when Δu'v '≤ 0.002. R _a : 82 General color rendering index, the value of 90 corresponds to "good to very good" R _1-14 76.76 Average of the color rendering indices of the 14 test colors TCS01-TCS14; the value of 86 corresponds to "good to very good" C * _(red) 70.46 CIELAB chroma (a term similar to saturation), this value corresponds to the accentuation of red object colors. The higher the value, the more saturated the illuminated red objects. R ₉ 6.29 Special color rendering index for red object colors, the value of 90 corresponds to "good" color rendering for red objects

For a weight of 0.0000 of the orange channel is obtained, as shown in Table 12, an emission spectrum with only moderate Δu'v ', R _a and R _1-14 value, and poor R ₉ value. That is, the quality of the white tone, the general color rendering index, and the average of the specific color rendering indices are all modest. The special color rendering index for red object colors is also poor.

Another embodiment of an LED lamp according to the invention is implemented in 6-channel technology. Specifically, the second embodiment of the LED lamp according to the invention comprises a first blue LED B, which generates light in a deep blue spectral range with an intensity peak in the wavelength range of about 450 nm to 455 nm, specifically at about 453 nm. The blue LED B of the second embodiment is constructed identical to the blue LED B of the first embodiment in 4-channel technology.

There is also provided a further blue LED B2, which emits primarily blue light with an intensity peak in the wavelength range from about 465 nm to 470 nm, specifically at about 468 nm.

A further provided green phosphor-converted LED G is identical in its construction with the green phosphor-converted LED G of the embodiment described above.

The same applies to a provided in the second embodiment of the LED lamp orange phosphor converted LED O.

In the illustrated embodiment in 6-channel technology also come instead of a red phosphor converted LED - as in the first Embodiment - two semiconductor LEDs emitting primarily in the red spectral range are used.

Specifically, a first red LED R1 is provided, which is characterized by an intensity peak with a maximum wavelength in the range of 625 nm and 635 nm, specifically at about 630 nm.

In addition, the illustrated embodiment of the LED lamp according to the invention on a second red LED R2, which emits primarily light with a spectrum that is characterized by an intensity peak with a maximum wavelength in the range of about 660 nm to 670 nm, specifically at about 665 nm distinguished.

The half widths of the peaks of the first blue LED B, the second blue LED B2, the first red LED R1 and the second red LED R2 are all about 20 nm.

The FIG. 7 shows a cool white white light spectrum at 5500 K with good color rendering (R _a = 90) to emphasize a red body color, which has been produced with the described second embodiment of an LED lamp according to the invention in 6-channel technology.

Table 13 shows the weighting of the emission spectra of the six channels (that is, drive signals of the LED channels) to that in the FIG. 7 to achieve the emission spectrum E shown. A weight of 1.0000 corresponds to the maximum control of the respective channel, other values are scaled linearly proportional. Table 13: LED channel LED channel LED channel LED channel LED channel LED channel B1 B2 G O R1 R2 .2309 .1348 .2108 0.0879 0.0000 1.0000

Table 14 contains the colorimetric properties that are consistent with the weighting factors from Table 13 for the example of FIG. 7 result. Table 14: Colorimetric properties of the example of FIG. 7. parameter value statement CCT: 5505 Most similar color temperature, 2700K: warm white, 4000 K: neutral white; 5500 K: cool white Δu'v ': 0.00200 Distance from the Planckian curve (for warm white and neutral white) or from the curve of the daylight phases (for cold white), which describes the quality of the white. The quality is perceptually acceptable iA when Δu'v '≤ 0.002. R _a : 90 General color rendering index, the value of 90 corresponds to "good to very good" R _1-14 84.01 Average of the color rendering indices of the 14 test colors TCS01-TCS14; the value of 86 corresponds to "good to very good" C * _(red ) 70.61 CIELAB chroma (a term similar to saturation), this value corresponds to the accentuation of red object colors. The higher the value, the more saturated the illuminated red objects. R ₉ 3.34 Special color rendering index for red object colors, the value of 90 corresponds to "good" color rendering for red objects

Finally, the shows FIG. 8 an emission spectrum E, which is a warm white white light spectrum at 2700 K with good color rendering (R _a = 90) to emphasize a red body color, which produces with the described second embodiment of an LED lamp according to the invention in the 6-channel technique has been.

Table 15 shows the weighting of the emission spectra of the six channels (ie LED channel drive signals) to match that in FIG. 8 to achieve the emission spectrum E shown. A weight of 1.0000 corresponds to the maximum control of the respective channel, other values are scaled linearly proportional. Table 15: LED channel LED channel LED channel LED channel LED channel LED channel B1 B2 G O R1 R2 0.0308 0.0382 0.0866 .1217 0.0000 1.0000

Table 16 contains the colorimetric properties that match the weighting factors from Table 15 for the example of FIG. 8 result. Table 16: Colorimetric properties of the example of FIG. 8. parameter value statement CCT: 2705 Most similar color temperature, 2700K: warm white, 4000 K: neutral white; 5500 K: cool white Δu'v ': 0.00200 Distance from the Planckian curve (for warm white and neutral white) or from the curve of the daylight phases (for cold white), which describes the quality of the white. The quality is perceptually acceptable iA when Δu'v '≤ 0.002. R _a : 90 General color rendering index, the value of 90 corresponds to "good to very good" R _1-14 85.33 Average of the color rendering indices of the 14 test colors TCS01-TCS14; the value of 86 corresponds to "good to very good" C * _(red) 74.93 CIELAB chroma (a term similar to saturation), this value corresponds to the accentuation of red object colors. The higher the value, the more saturated the illuminated red objects. R ₉ 22.34 Special color rendering index for red object colors, the value of 90 corresponds to "good" color rendering for red objects

Claims (15)

LED luminaire having a lighting unit, which has a plurality of LEDs (R, G, B) which are designed to emit light in the primary colors red and green and blue of a color system, and a control unit which is coupled to the lighting unit and formed is to drive the LEDs in such a way that they additively generate light of a desired spectrum, characterized in that the illumination unit has an orange phosphor converted LED (O), which in particular emits primarily light in a blue spectral range, wherein the orange phosphor converted LED (O) is provided with a luminescent substance or luminescent substance mixture which is in particular formed completely in light, the spectrum of which has at least wavelengths in the range from 570 to 610, in particular from 560 to 620 nm, preferably 550 to 640 nm, with the LEDs (B, G, R, O) of the lighting unit being controlled by the control unit beauty are controlled via separate control channels. LED luminaire according to claim 1, characterized in that the phosphor or the phosphor mixture of the orange phosphor-converted LED (O) is formed to the primary emitted light in particular completely in light whose spectrum has a wavelength of maximum intensity in the wavelength range between 570 and 620 nm, in particular between 580 and 600 nm, preferably between 590 and 600 nm. LED luminaire according to claim 1 or 2, characterized in that the illumination unit comprises a green phosphor-converted LED (G) which emits in particular primarily light in a blue spectral range, wherein the green phosphor converted LED (G) with a phosphor or Phosphor mixture which is or is formed to convert the primary emitted light in particular completely into light whose spectrum has at least wavelengths in the range from 500 nm to 540 nm, in particular 490 to 550 nm, preferably 480 to 570 nm; wherein in particular the phosphor or the phosphor mixture of the green phosphor-converted LED (G) is designed to the primary emitted light in particular completely in light whose spectrum has a maximum intensity wavelength in the wavelength range between 490 and 530 nm, in particular between 500 and 530 nm, preferably between 510 and 520 nm to convert. LED luminaire according to claim 3, characterized in that the green and the orange phosphor converted LED (G, O) emit primarily light in the blue spectral range, in particular the green and the orange phosphor converted LED (G, O) with the exception of the respective phosphor or Phosphor mixtures are of identical construction. LED luminaire according to one of the preceding claims, characterized in that the illumination unit has a red phosphor-converted LED (R) which emits in particular primarily light in the blue or green spectral range, wherein the red phosphor converted LED (R) is provided with a phosphor or phosphor mixture which is or is designed to convert the primary emitted light in particular completely into light whose spectrum has at least wavelengths in the range of 620 nm to 670 nm, in particular 610 to 680 nm, preferably 600 to 690 nm, wherein in particular the Phosphor or the phosphor mixture of the red phosphor converted LED (R) is adapted to the primary emitted light in particular completely in light whose spectrum has a wavelength of maximum intensity in the wavelength range between 630 and 670 nm, especially between 640 and 660 nm, preferably between 645 and 655 nm. LED luminaire according to claim 5, characterized in that the red phosphor converted LED (R) primarily emits light in the blue spectral region, in particular the red phosphor converted LED (R) with the exception of the phosphor or phosphor mixture identical to the green and / or orange phosphor converted LED (G, O) is formed. LED luminaire according to one of claims 1 to 4, characterized in that the illumination unit has a red LED (R1) which emits primarily light in a red spectral range, wherein in particular the red LED (R1) is formed, light of a spectrum with a Intensity peak with a central wavelength in the wavelength range between 610 and 650 nm, in particular between 620 and 640 nm, preferably between 625 and 635 nm, and in particular the intensity peak of the red LED (R1) has a half-width of at least 15 nm, preferably at least 20 nm, and in particular the illumination unit has a further red LED (R2), which primarily emits light in a further red spectral range, wherein in particular the further red LED (R2) is adapted to light a spectrum with an intensity peak with a central wavelength in the wavelength range between 650 and 680 nm, in particular between 660 and 670 nm to emit, and wobe In particular, the intensity peak of the further red LED (R2) has a half-value width of at least 15 nm, preferably at least 20 nm. LED luminaire according to one of the preceding claims, characterized in that the illumination unit has a blue LED (B), which emits primarily light in a blue spectral range, wherein in particular the blue LED is formed, light of a spectrum with an intensity peak in the wavelength range between 430 and 470 nm, in particular between 440 and 465 nm, preferably between 450 and 455 nm, and wherein in particular the intensity peak of the blue LED (B) has a half-width of at least 15 nm, preferably at least 20 nm, and in particular the illumination unit has a further blue LED (B2) which primarily emits light in a blue spectral range, wherein in particular the further blue LED (B2) is formed, light of a spectrum with an intensity peak with a central wavelength in the wavelength range between 450 and 480 nm, in particular between 465 and 475 nm, preferably between 465 and 470 nm, and in which, in particular, the intensity peak of the further blue LED (B2) has a half-width of at least 15 nm, preferably at least 20 nm. LED light according to one of the preceding claims, characterized in that the LEDs (B, G, R, O) are driven to produce a white light spectrum at about 2700 K with very high color rendering, in particular the control channels of the LEDs (B, G, R, O) are controlled with the following percentages of a given, in particular maximum activation value for the respective color: Blue LED (B): 25-35%, in particular 28-32%, preferably 29.88%, Green fluorescent converted LED (G): 55-65%, in particular 60-64%, preferably 62.64%, orange fluorescent converted LED (O): 50-60%, in particular 52-56%, preferably 54.12%, red phosphor converted LED (R): 90-100%, especially 100%. LED lamp according to one of claims 1 to 8, characterized in that the LEDs (B, G, R, O) for generating a neutral white White light spectrum are driven at about 4000 K with very high color rendering, in particular the control channels of the LEDs (B, G, R, O) are controlled with the following percentages of a predetermined, in particular maximum activation value for the respective color: Blue LED (B): 90-100%, especially 100%, Green fluorescent converted LED (G): 80-90%, in particular 82-98%, preferably 85.92%, orange fluorescent converted LED (O): 42-55%, in particular 45-50%, preferably 47.89%, red phosphor converted LED (R): 65-75%, in particular 68-72%, preferably 69.40%. LED lamp according to one of claims 1 to 8, characterized in that the LEDs (B, G, R, O) are driven to produce a cold white white light spectrum at about 5500 K with very high color rendering, in particular the control channels of the LEDs (B , G, R, O) are controlled with the following percentages of a given, in particular maximum activation value for the respective color: Blue LED (B): 90-100%, especially 100%, Green fluorescent converted LED (G): 60-70%, in particular 62-65%, preferably 63.95%, orange fluorescent converted LED (O): 15-25%, in particular 18-22%, preferably 20.01%, red phosphor converted LED (R): 35-45%, especially 36-40%, preferably 38.26%. LED lamp according to one of claims 1 to 8, characterized in that the LEDs (B, G, R, O) for producing a warm white White light spectrum at about 2700 K are driven with good color rendering to emphasize a red body color, in particular the control channels of the LEDs (B, G, R, O) are controlled with the following percentages of a predetermined, in particular maximum activation value for the respective color: Blue LED (B): 25-35%, in particular 26-30%, preferably 28.23%, Green fluorescent converted LED (G): 50-60%, in particular 52-58%, preferably 54.33%, orange fluorescent converted LED (O): 30-40%, in particular 32-38%, preferably 35.83%, red phosphor converted LED (R): 90-100%, especially 100%. LED lamp according to one of claims 1 to 8, characterized in that the LEDs (B, G, R, O) are driven to produce a neutral white white light spectrum at about 4000 K with good color rendering to emphasize a red body color, in particular the control channels of the LEDs (B, G, R, O) are controlled with the following percentages of a predetermined, in particular maximum activation value for the respective color: Blue LED (B): 88-98%, in particular 90-94%, preferably 92.80%, Green fluorescent converted LED (G): 85-95%, in particular 89-94%, preferably 91.89%, orange fluorescent converted LED (O): 20-30%, in particular 24-29%, preferably 26.01%, red phosphor converted LED (R): 90-100%, especially 100%. LED light according to one of claims 1 to 8, characterized in that the illumination unit has a red and another red LED (R1, R2) and a blue and another blue LED (B, B2), and the LEDs (B, B2, G, O, R1, R2) are driven to produce a cold white white light spectrum at about 5500 K with good color rendering to emphasize a red body color, in particular the control channels of the LEDs with the following percentages of a predetermined, in particular maximum activation value for the respective color driven become: Blue LED (B): 18-28%, especially 20-25%, 23.09%, further blue LED (B1): 8-18%, especially 10-15%, 13.48%, Green fluorescent converted LED (G): 15-25%, in particular 19-24%, preferably 21.08%, orange fluorescent converted LED: 3-13%, in particular 6-11%, preferably 8.79%, red LED: 0-5%, especially 0%, another red LED: 90-100%, especially 100%. LED lamp according to one of claims 1 to 8, characterized in that the illumination unit has a red and another red LED and a blue and another blue LED, and the LEDs for generating a warm white white light spectrum at about 2700 K with good color rendering for In particular, the control channels of the LEDs are controlled with the following percentages of a predetermined, in particular maximum activation value for the respective color: Blue LED (B): 0-8%, especially 1-5%, 3.08%, further blue LED (B1): 0-8%, especially 1-6%, 3.82%, Green fluorescent converted LED (G): 5-15%, especially 5-10%, preferably 8.66%, orange fluorescent converted LED (O): 8-18%, in particular 10-15%, preferably 12.17%, red LED (R1): 0-5%, especially 0%, further red LED (R2): 90-100%, especially 100%.

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