DE102014206019A1 - LED array - Google Patents

Abstract

Disclosed is an LED array with at least one exciting LED whose light is convertible via a phosphor in cyan or mint light. The arrangement further has at least one red emitting LED. According to the invention, all the LEDs of the arrangement, that is to say the exciting LED (s) and the red-emitting LED (s), are mounted on a common conductor plate.

Description

Technical area

The invention is based on LED assemblies in which several different colored LEDs are grouped to produce white light.

State of the art

According to the state of the art, in the energy-saving LED technology, white light is generated by various LEDs via additive color mixing. In this case, phosphors can be used. It is known, for example, to combine a blue-emitting LED with another blue-emitting LED whose light is converted to yellow light via a phosphor. Furthermore, it is known to generate red, green and blue light by LEDs and phosphors and mix. In both examples, white light is produced by additive color mixing.

More particularly, the invention relates to LED arrays in which red and cyan or mint colored light are mixed to produce white light. The white light thus generated has a high spectral efficiency. In this case, the individual LEDs are structurally separated from each other according to the prior art.

Presentation of the invention

The object of the present invention is to provide an LED arrangement with reduced device complexity and space requirement, in which light from sources with different wavelength ranges, in particular red and blue-green light, are mixed. In the context of this application, the term "red light" is to be understood in particular as meaning electromagnetic radiation in a wavelength range from 600 nm to 700 nm, while cyan light in the context of this application in particular comprises a wavelength range from 450 nm to 500 nm, preferably a wavelength of 480 nm. Mint-colored light can be generated in particular by a mixture of blue and green components, the wavelength range for blue light preferably being between 420 nm and 460 nm and that for green light preferably being between 495 nm and 550 nm.

This object is achieved by an arrangement with an LED that emits light in a first wavelength range, whose light is convertible via a phosphor into light in a second wavelength range, and with an LED that emits light in a third wavelength range, wherein the first wavelength range at least partially shorter wavelengths than the second wavelength range and the second wavelength range comprises at least partially shorter wavelengths than the third wavelength range, wherein the LED that emits light in a first wavelength range and the LED that emits light in a third wavelength range, on a common conductor plate are mounted.

Particularly advantageous embodiments can be found in the dependent claims.

It is advantageous if the third wavelength range comprises wavelengths of 600 nm to 700 nm. This is perceived as a red light. LEDs that radiate in this wavelength range have a particularly good efficiency.

Furthermore, it is expedient if the second wavelength range comprises wavelengths of 450 nm to 500 nm, preferably 480 nm. This is perceived as cyan light. It may also be expedient if the second wavelength range corresponds to that of mint-colored light, i. a mixture of light from two wavelength ranges.

In a particularly preferred development, the LED, which emits light in a third wavelength range, is a surface emitter, so that it emits light only over its surface (for example red). This reduces absorption and increases the efficiency of the LED array.

In this case, the at least one LED, which emits light in a third wavelength range, may be a thin-film LED.

The at least one LED, which emits light in a first wavelength range, may be a volume emitter which radiates stimulating light to the phosphor via its surface and its sides.

The LED array is particularly energy efficient when the at least one LED that emits light in a first wavelength range is blue emitting. The wavelength range for blue light in the context of this application is preferably between 420 nm and 460 nm.

It is preferable that the LED that emits light in a first wavelength range is a sapphire LED.

For effective excitation of the phosphor, it can cover and surround the LED, which emits light in a first wavelength range. In this case, the phosphor remains to prevent absorption of the at least one LED, the light radiates in a third wavelength range, spaced.

It is simpler in terms of manufacturing technology if, for the purpose of avoiding absorption, the phosphor covers and surrounds at least one LED which emits light in a first wavelength range and also surrounds the at least one LED which emits light in a third wavelength range, ie in lateral contact with the LED that emits light in a third wavelength range stands. This may in particular mean that the surface of the LED, which emits light in a third wavelength range, is free of phosphor.

As "lateral" or "top" and related names are in the context of this application in particular directional information to be considered, indicating the directions perpendicular or parallel to a Hauptabstrahlrichtung an LED and / or a mounting surface for the LED.

According to a preferred first variant, the printed circuit board has one or more elevations on which one or more LEDs emitting light in a third wavelength range are mounted. In this case, the at least one exciting LED is mounted spaced from the elevation or adjacent to the elevation to a lower level of the circuit board.

According to a preferred second variant, the printed circuit board has recesses in which one or more LEDs which emit or radiate light in a first wavelength range are or are mounted. In this case, the at least one LED, which emits light in a third wavelength range, is mounted at a distance from the depression or adjacent to the depression to a higher level of the printed circuit board.

In both variants, the LEDs which emit light in a third wavelength range are increased in relation to the LEDs which emit light in a first wavelength range, so that a surrounding - e.g. encapsulate - the LEDs that emit light in a first wavelength range is possible with phosphor without the LEDs that emit light in a third wavelength range, are covered with phosphor, and without their light in the LED assembly according to the invention mix and can absorb.

In this case, the printed circuit board may be a punched leadframe with wavy cross-section or a ceramic circuit board.

In a preferred embodiment, the surface of the at least one LED which emits light in a third wavelength range results, and the surface of the phosphor approximately a plane.

In a manufacturing technology simple variant, the circuit board is flat or even. Then, an uneven surface of the phosphor may result, especially if it forms a curvature over the LED, which emits light in a first wavelength range.

Brief description of the drawings

In the following, the invention will be explained in more detail with reference to exemplary embodiments. The figures show:

1 a first embodiment of an LED arrangement according to the invention;

2 A second embodiment of an LED array according to the invention and

3 A third embodiment of an LED arrangement according to the invention.

Preferred embodiment of the invention

1 shows a detail of a first embodiment of an LED arrangement according to the invention in a side sectional view. It has a ceramic circuit board 1 whose bottom is flat. At the top of the circuit board 1 are evenly distributed over the surface elevations 2 provided, of which in 1 only two increases 2 are shown. On every increase 2 is a red thin-film LED 4 assembled.

In between the elevations 2 formed depressions 6 are also distributed evenly blue sapphire LEDs 8th arranged, of which in 1 only two sapphire LEDs 8th are shown. Thus results on the surface of the circuit board 1 an LED array with evenly distributed LEDs 4 . 8th different design and light color.

Areas above and beside the blue sapphire LEDs 8th and beyond that all areas between the red thin-film LEDs 4 are with fluorescent 10 filled. This phosphor 10 is through the blue sapphire LEDs 8th stimulated to glow and gives off cyan or mint green light. The exit of the cyan light is decoupled from the exit of the red light, which in each case only over a surface 12 the red thin-film LED 4 he follows.

2 shows a detail of a second embodiment of an LED array according to the invention in a side sectional view. Here is the structure of the LED array with the red LEDs 4 , the blue LEDs 8th and with the phosphor 10 comparable to the first embodiment according to 1 , Deviating from the first embodiment is a metallic circuit board 101 provided, wherein the different levels of the surface were produced by forming, for example by pressing. This will also be on the surface of the circuit board 101 increases 102 or between remaining wells 106 generated. At the circuit board 101 According to the second embodiment, the bottom is formed analogous to the top.

3 shows a detail of a third embodiment of an LED arrangement according to the invention in a side sectional view. Here is the structure of the LED array with the red LEDs 4 and the blue LEDs 8th comparable to the previous embodiments according to 1 and 2 , Deviating from the first embodiment is a conventional circuit board 201 provided, which is flat or flat at its bottom and at its top. As alternate only the blue LEDs 8th from the phosphor 201 are covered while the red thin-film LEDs 4 are uncovered at its top, results in the third embodiment, a wavy surface 114 of the phosphor 210 ,

In the three embodiments, the inventive optical decoupling of the red light is only from the surface 12 the red thin-film LED 4 leakage, and the cyan light, only from the surface 14 . 114 of the phosphor 10 . 210 exit, guaranteed.

LIST OF REFERENCE NUMBERS

1; 101; 201

 circuit board

2; 102

 increase

4

 red thin film LED

6; 106

 deepening

8th

 blue sapphire LED

10; 210

 fluorescent

12

 surface

14; 114

 surface

Claims (13)

LED arrangement with one LED ( 8th ), which emits light in a first wavelength range whose light is emitted via a phosphor ( 10 ; 210 ) is convertible into light in a second wavelength range, and with an LED ( 4 ), which emits light in a third wavelength range, wherein the first wavelength range at least partially shorter wavelengths than the second wavelength range and the second wavelength range at least partially shorter wavelengths than the third wavelength range, characterized in that the LED ( 8th ), which emits light in a first wavelength range and the LED ( 4 ), which emits light in a third wavelength range, on a common conductor plate ( 1 ; 101 ; 201 ) are mounted. LED array according to claim 1, wherein the third wavelength range comprises wavelengths of 600 nm to 700 nm LED arrangement according to claim 1 or 2, wherein the second wavelength range wavelengths of 450 nm to 500 nm, preferably 480 nm LED arrangement according to one of claims 1 to 3, wherein the LED ( 4 ), which emits light in a third wavelength range, is a surface emitter. LED arrangement according to one of claims 1 to 4, wherein the LED ( 4 ), which emits light in a third wavelength range, a thin-film LED ( 4 ). LED arrangement according to one of the preceding claims, wherein the LED ( 8th ), which emits light in a first wavelength range, is a volume emitter. LED arrangement according to claim 6, wherein the LED ( 8th ), which emits light in a first wavelength range, a sapphire LED ( 8th ). LED arrangement according to one of the preceding claims, wherein the phosphor ( 10 ; 210 ) the LED ( 8th ), which emits, covers and surrounds light in a first wavelength range and the LED ( 4 ), which emits light in a third wavelength range, surrounds. LED arrangement according to one of the preceding claims, wherein the printed circuit board ( 1 ; 101 ) one or more elevations ( 2 ; 102 ), on each of which at least one LED ( 4 ), which emits light in a third wavelength range, is mounted, and wherein the at least one LED ( 4 ) which emits light in a first wavelength range spaced from the elevation ( 2 ; 102 ) or adjacent to the increase ( 2 ; 102 ) on the printed circuit board ( 1 ; 101 ) is mounted or are. LED arrangement according to one of the preceding claims, wherein the printed circuit board ( 1 ; 101 ) one or more depressions ( 6 ; 106 ), in each of which at least one LED ( 4 ), which emits light in a first wavelength range, is mounted, and wherein the at least one LED ( 4 ), which emits light in a third wavelength range, spaced from the depression ( 6 ; 106 ) or adjacent to the recess ( 6 ; 106 ) on the printed circuit board ( 1 ; 101 ) is mounted. LED arrangement according to claim 7 or 8, wherein the printed circuit board is a punched leadframe ( 101 ) with wavy cross-section or a ceramic circuit board ( 1 ). LED arrangement according to one of the preceding claims, wherein a surface ( 12 ) of the at least one LED ( 4 ) which emits light in a third wavelength range, and a surface of the phosphor ( 10 ) form a plane. LED arrangement according to claim 1 to 6, wherein the printed circuit board ( 201 ) is substantially flat.

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