WO2014174083A1 - Led module for emitting white light ('pizza arrangement') - Google Patents

Abstract

The present invention relates to an LED module (1) that is suitable for emitting mixed light, preferably white light. The LED module (1) has a light-emitting light field (2) that is divided into a plurality of regions for emitting different light spectra. The regions of the light field (2) are planar sectors (3a, 3b, 3c) according to the invention. The LED module (1) is produced by a method in which, for creating the light field (2), first barriers (5) are formed which separate sectors (3a, 3b, 3c) of the light field (2) from each other, and then a transparent casting compound or a casting compound containing a luminescent substance is filled between the barriers (5) of each sector (3a, 3b, 3c). The present invention thereby provides a lighting device that has at least one LED module (1) and preferably one reflector placed on the LED module (1).

Description

 LED module for emitting white light ("pizza arrangement")

The present invention relates to an LED module for dispensing

Mixed light, preferably white light, and a method for producing such an LED module. In particular, the present invention relates to an LED module suitable for lamps having my reflector sizes. The present invention finally relates to a lighting device with built-in LED module. From the prior art LED modules are known which are suitable for emitting white light. These LED modules usually have a light-emitting light field, which is formed by a combination of individual light points. The individual points of light are designed to emit different light spectra. For example, blue light, red light and yellow light generated by a phosphor are emitted from the light spots.

Such a known LED module 10 is shown for example in Fig. La. Fig. Lb shows a top view of the same LED module 10. The LED module 10 has a light field 12, which together with others

 Components 18 is arranged on a module plate 17. The light field 12 is formed of a plurality of light spots 13a, 13b, 13c, each of light from a different wavelength range, d. H. another light spectrum. Each of the light spots 13a, 13b, 13c, as shown in Fig. Lb, associated with at least one LED 16. The light spots 13a, 13b, 13c are generally formed by so-called glob tops (drops of disperse) above the LEDs 16.

The known LED module 10 has the disadvantage that it is too large

Light field 12 has to implement it with small reflector sizes. In particular, FIG. 1b shows that the light field 12 has a diameter of at least 19 mm. With the Glob Top method, it is not possible to further reduce the diameter of the light field 12. The object of the present invention is to provide an LED module for emitting mixed light, preferably white light, which improves the known state of the art. In particular, it is an object of

present invention to provide an LED module that is suitable for lights with small reflector sizes. For this purpose, it is an object of the present invention to reduce a total light emitting surface of an LED module.

The present invention is solved by the independent claims. The dependent claims form the core idea of the present

Invention in an advantageous manner on.

More particularly, the present invention relates to an LED module for emitting mixed light, preferably white light, comprising a light field divided into a plurality of regions for outputting different light spectra, the regions of the light field being areal sectors.

The light field is a light emitting surface of the LED module according to the invention. Due to the planar sector distribution of the light field, it is possible to significantly reduce the total area of the light field in comparison with the total area of a known LED module containing points of light defined by glob tops. Due to the sector arrangement, the total light emission surface of the light field can in particular be reduced by at least 16%. Such a reduction is not possible with the glob top approach known from the prior art. Due to the significant reduction in area of the light field, the LED module according to the invention is also suitable for lights with small reflector sizes.

Advantageously, at least two area sectors are provided for each light spectrum.

The LED module according to the invention is designed, for example, to emit three different light spectra. In each case a light spectrum is coupled out of at least two of the area sectors of the light field. As a result, a very homogeneous and color-true mixed light, in particular white light, can be generated by the LED module as a whole.

The outer contour of the light field is preferably round. Advantageously, the outer contour of the light field is circular. The circular shape is particularly advantageous for lights that have optics with attached reflector.

Advantageously, circular sectors of the circular light field for

Dispensing of at least one light spectrum designed. In addition, circular islands may be provided in the light field for outputting at least one other spectrum of light, which may be advantageous to

Emitting light from the red light spectrum are designed.

Both the circular sectors and the circular islands in the light field are area sectors. By this advantageous arrangement of the flat

Sectors in the light field, for example, an LED module can be formed which emits mixed light of three or more different light spectra and thereby has a particularly small Gesamtlichtabstrahlfläche. The light field can thus be reduced in area.

As a result, on the one hand, a particularly small light field can be formed. On the other hand, the light field is suitable for emitting white light of a particularly natural light color temperature. The circular sectors are preferably designed for emitting red, blue light and light from a further light spectrum, which is generated by a phosphor. This further light spectrum can be, for example, light from the green and / or yellow light spectrum. As noted above, in addition circular islands can be provided for emitting red light, so that in this case no red light would have to be provided by the circular sectors.

Advantageously, the light field has a diameter of 16 mm or less. By this compared to the prior art significantly reduced light field diameter, the LED module according to the invention is adapted to implement a lamp with small reflector sizes. Advantageously, the LED module further comprises a light diffusion plate, which is arranged at a distance from the light field in the light emission direction of the light field.

The light diffuser gives the LED module a more homogeneous

Color impression, i. the scattering of the light improves the mixing of the different light spectra emitted by the light field. The light diffuser also makes it possible to generate a diffused light and adjust the brightness of the LED module. The

Lichtstreuscheibe may additionally be provided with a phosphor, for example with an additional phosphor layer or embedded phosphor particles. The diffuser is then suitable for influencing the color or color temperature of the light emitted by the LED module as a whole. Advantageously, the lens is separated by a mixing chamber from the top of the light field.

The mixing chamber preferably ensures a particularly effective

Mixing of the different light spectra, which are emitted by the flat sectors of the light field. For a viewer of the LED module then a very homogeneous mixed light is visible. The individual area sectors of the light field or the emitted thereof

different light spectra are preferably not visible from the outside for a viewer.

Advantageously, the light field is made with the planar sectors by dams and filling. This method, also known as the "dam-and-fiU" method, makes it particularly easy to produce the two-dimensional sectors of the light field.The method enables a much smaller light field than can be achieved with the well-known Glob Top method Prefabricated component which is mounted on a module plate of the LED module.

Advantageously, the planar sectors of the light field are separated from each other by dams.

Advantageously, the two-dimensional sectors of the light field comprise a transparent potting compound or a phosphor containing

Sealing compound. Preferably, in the LED module according to the invention, the individual sectors of the light field are defined by the limiting dams and in the

Gaps between the dams is filled with potting compound to make the sectors flat. The potting compound can from a

transparent potting compound with added phosphor exist, which is present for example as an undissolved powder or as phosphor particles. The potting compound may also contain dissolved phosphors, i. it can be a phosphor potting compound.

A phosphor is generally a material that is excitable by light and then emits a secondary spectrum of light. A phosphor may therefore be a light color conversion material. For example, the phosphor is a phosphor or a fluorescent material. Secondary light from the yellow and / or green spectrum is preferably emitted by the phosphor.

Advantageously, the planar sectors are designed at least for emitting light from the red light spectrum, light from the blue light spectrum or light from a further light spectrum generated by a phosphor. The present invention understands light from the red light spectrum light having a wavelength between about 630 and 790 nm, light from the blue light spectrum light having a wavelength between about 390 to 480 nm, light from the green light spectrum light having a wavelength between about 480 and 560 nm and under light from the yellow light spectrum light of a wavelength between 560 and 630 nm.

The LED module according to the invention is thereby suitable for emitting white light, in particular natural-looking white light. Natural-looking white light preferably has a light color temperature that corresponds to that of a black body.

Advantageously, the planar sectors are each provided with at least one LED or one LED strand.

The at least one LED or the at least one LED string (i.e., multiple interconnected LEDs) preferably sits between the baffles of the individual sectors on a module plate of the LED module. Preferably, the LED or the LED strand are potted with the potting compound. This fixes and protects the LEDs or the LED string. The light emitted by the LED or the LED strand is transported by the potting compound from the LED module and optionally influenced or converted by a phosphor in the potting compound. The LEDs may be, for example, blue-emitting, red-luminescent, green-luminescent, yellow-emitting or UV-emitting LEDs. That delivered by a surface sector

Light spectrum can come about through an interaction between at least one LED and the potting compound, or be generated directly from the at least one LED.

The present invention further relates to a method for producing an LED module for emitting mixed light, preferably white light, comprising the steps of: generating a light field which is subdivided into area sectors by forming dams, which sectors of the light field Separate, and filling a transparent potting compound or a phosphor-containing potting compound between the dams of each sector. By erfmdungsgemäße method, an LED module with

area-reduced light field are produced. The reduced area of the light field can not be achieved by a conventional Glob Top method.

The present invention further relates to a lighting device having at least one LED module as described above and preferably a reflector set on the LED module.

The luminaire is designed especially for small reflector sizes. For this purpose, the LED module according to the invention, in particular its area-reduced light field is a necessary prerequisite.

The present invention will now be described in more detail with reference to the accompanying drawings. Figures la and lb show an LED module known in the art.

Figures 2a and 2a show a first LED module according to the present invention.

Fig. 3 shows an alternative embodiment of a light field for LED module according to the present invention.

FIG. 4 shows a further alternative embodiment of a light field for an LED module according to the present invention.

Fig. 5 shows the light field shown in Fig. 4 again, in Fig. 5, the respective LED strands and their interconnection are indicated. FIG. 2a shows a three-dimensional lateral view of a first exemplary embodiment of an LED module 1 according to the invention. The LED module 1 is suitable for emitting mixed light, for example for emitting white light. For this purpose, different emitted light spectra are mixed in the LED module l in such a way that the mixed light or the white light of the LED module 1 is produced as an overall impression for a viewer.

The LED module 1 according to the invention has a module plate 7, on which at least one light field 2 is arranged, which is designed to emit the light of the LED module 1. The light field 2 emits the light from its surface area. Furthermore, are advantageously on the

Module plate 7 even more components 8 are arranged. These further components 8 may be, for example, electronic components such as drive components, microprocessors, capacities,

 Inductors, resistors, electrical leads or the like. The electronic components can supply and / or control LEDs 6 or LED strings of the LED module 1 with energy. The others

Components 8 may also include cooling elements for dissipating heat from the module plate 7 and the light field 2, respectively. Furthermore, the

 Module plate 7 to be provided with attachment means for attaching the LED module 1 in example, a light housing. For example, as shown in FIG. 1 a, the module plate 7 has holes for screwing on the LED module 1. The module plate 7 may be, for example, a printed circuit board such as a printed circuit board (PCB). The module plate 7 is advantageously at least partially formed from a material which is used for

Heat dissipation is suitable.

The light field 2 of the LED module 1 is subdivided into a plurality of areal sectors 3a, 3b, 3c. Each of the sectors 3a, 3b, 3c is designed to emit light from a specific light spectrum. The light field 2 preferably comprises at least a first type of sectors 3a, which emit light from a first light spectrum, and a second type of sectors 3b, which emit light from a second light spectrum. Preferably, this includes Light field 2 is also a third type of sectors 3c, which emit light from a third light spectrum. Of course, more different types of sectors can be used, giving off altogether four or even more different light spectra.

For each emitted light spectrum, the light field 2 preferably comprises at least two sectors 3 a, 3 b, 3 c. For example, to generate white light as the mixed light, the light field 2 may include a first type of sectors 3a that emit light from a blue light spectrum, a second kind of sectors 3b that emit light from a red light spectrum, and a third kind of Sectors 3c, which emit light from a further spectrum of light that of a phosphor such

for example, a phosphor is generated. This further light spectrum advantageously comprises the green and / or yellow light spectrum.

Due to the fact that in the LED module 2 according to the invention the different regions of the light field 2 which emit different light spectra are not formed by light points but by area sectors 3a, 3b, 3c, a reduction of the total area of the light field 2 is possible. The total light emission surface of the LED module 1 can therefore be reduced.

Preferably, as shown in Figs. 2a and 2b, the light field 2 is round.

In particular, the light field 2 most preferably has one

circular outer contour, but may also be oval, elliptical or the like. The diameter of the light field 2 is preferably 16 mm or even less. The area of the light field 2 may be about 200 mm ² or less and is reduced by 16% in comparison with the prior art. As shown in FIG. 2a, the circular light field 2 preferably has a subdivision into different types of circular sectors 3a and 3b.

As shown in FIG. 2 a, the light field 2 preferably also has a plurality of circular islands 3 c which are located within the outer contour of the light field 2 are arranged. For example, as shown in Fig. 2a, a circular island 3c may form the center of the light field 2, ie, for example, may form the center of the circular outer contour. In addition, further circular islands 3c may for example be arranged at regular intervals along the circumference of the Liehtfeldes 2. In one

preferred example, the light field 2, as shown in Fig. 2a, a total of eight circular sectors 3a and 3b. However, the inner division of the planar sectors 3a, 3b, 3c of the light field 2 can also have other shapes than those shown here (cf., for example, FIG. 3).

Preferably, the circular islands 3 c are provided for emitting light from the red spectrum. The true circular sectors 3a and 3b are preferably provided for emitting light from the blue and / or a further light spectrum, which is generated for example by a phosphor. By selecting the diameters of the circular islands 3c and / or the surfaces of the circular sectors 3a and 3b during the manufacturing process of the LED module 1, the color of the LED module 1 or its color temperature can be set. The planar sectors 3a, 3b, 3c of the light field 2 are preferably formed by dams and filling. For this purpose, dams 5 are formed on the module plate 7 of the LED module in a first step, which determine the subsequent structure of the sectors 3a, 3b, 3c. By a dam 5 while the outer contour of the light field 2 is formed. For subdivision sectors 3a, 3b, 3c, for example rectilinear or curved dams 5 are drawn within the outer contour of the light field 2. For the formation of circular islands circular dams 5 within the

Outer contour of the light field 2 are formed. Once the dams 5 are formed on the module plate 7, the spaces defined thereby are filled. The filling is carried out either with a transparent potting compound or with a potting compound which is provided with a phosphor, for example with phosphor particles. Phosphor particles may be in the potting compound as a powder Be provided phosphor. Even the potting compound itself can

have light-converting properties. A phosphor is generally characterized in that it can be excited by the light of an LED 6 and then emits a secondary light spectrum.

In each planar sector 3a, 3b, 3c, at least one LED 6 or an LED string is preferably arranged before the filling step. However, these can also be previously embedded in the module plate 7 and the sectors 3a, 3b, 3c are thus formed on the LEDs 6. The dams 5 can also be formed around arranged on the module plate 7 LEDs 6 and LED strands around. The LEDs 6 or LED strands are preferably enclosed by the potting compound, which is filled between the dams 5. The LEDs 6 or LED strands are on the module plate 7 with power supply and preferably controllable.

Those sectors 3a, 3b, 3c which are filled with a transparent potting compound are designed to emit light emitted by one or more LEDs 6 unchanged. For example, of such sectors 3a, 3b, 3c, red and / or blue light can be emitted by a red-emitting and / or blue-emitting LED 6. Those sectors 3a, 3b, 3c which are filled with a potting compound containing a phosphor, on the other hand, are adapted to emit light emitted by one or more LEDs 6 in a changed manner. This happens, for example, in that the light of these LEDs 6 excites the phosphor in the potting compound, whereby a secondary light spectrum is emitted from this. For example, yellow light or green light can thereby be generated and emitted.

In the light field 2 of the LED module 1 according to the invention, each planar sector 3a, 3b, 3c may be provided with a potting compound that can change the light of the enclosed LED 6 or only some of the sectors 3a, 3b, 3c. It is even possible that each individual sector 3a, 3b, 3c of the light field 2 itself is designed to produce a white light. For example, in each sector 3a, 3b, 3c, a blue luminous LED 6 can be used, and can be used for each sector, a different phosphor potting compound as a filling. As a result, a white light is generated by a combination of three different white lights and it can be achieved a particularly natural color temperature.

The LEDs 6 or LED strands in the various sectors 3 a, 3 b, 3 c of the light field 2 may be individually or jointly controllable such that their luminous color is variable by the control. Furthermore, preferably each LED 6 or LED track can be dimmed individually, for example by means of pulse width modulation.

2b shows a plan view of the LED module 1. As shown, in front of the light emitting surface of the light field 2, a lens 4 may be arranged, which is shown here as a dashed circle. The diffuser 4 has at least the same diameter as the light field 2, preferably a larger diameter. The diffusing screen 4 may be provided with scattering particles which are selected such that they scatter the light emitted by the light field 2. For this purpose, the scattering particles have a particle size which corresponds approximately to the wavelength of the emitted light spectra. Preferably, the lens 4 is spaced from the top of the light field 2.

Between the upper side of the light field 2 and the diffusing screen 4, a so-called mixing chamber is preferably present. In the simplest case, the mixing chamber is merely a free space between the light field 2 and the diffuser 4. The mixing chamber is, however, preferably designed to achieve an effective mixing of the different light spectra emitted by the light field 2. For this purpose, optical elements may be provided in the mixing chamber, for example. Optical elements are, for example, lenses or reflectors. However, the mixing chamber may also be a solid block of a material having a high refractive index, for example, of 1.5 or more. Overall, it is achieved by the mixing chamber and the diffuser 4 together that the individual light spectra from the different area sectors 3a, 3b, 3c of the light field 2 are emitted, no longer from one

Viewers of the LED module 1 are distinguishable, but appear as a homogeneous mixed light, preferably homogeneous white light. FIG. 3 shows an alternative embodiment of a light field 2 'for an LED module according to the present invention.

In contrast to the light field 2 shown in FIGS. 2 a and 2 b, the light field 2 'comprises no circular islands 3 c but only one circular sector 3 a', 3 V and 3 'for emitting light from one

certain light spectrum. The light field 2 'comprises a first sector 3a, the light from a first light spectrum, a second sector 3b, the light from a second light spectrum and a third sector 3c, which can emit light from a third light spectrum.

4 shows a further alternative embodiment of a light field 2 "for an LED module according to the present invention: Again, the light field 2" does not comprise circular islands 3c but respectively different sectors 3a ", 3b" and 3c " Light field 2 "a first type of sectors 3a", the light from a first light spectrum, a second type of sectors 3b ", the light from a second light spectrum and a third type of sectors 3c", which can emit light from a third light spectrum. 5 again shows the light field 2 "illustrated in FIG. 4, the respective LED strands 6" and their interconnection being indicated in FIG. 5. As can easily be seen in FIG. 5, the connecting leads 7 "are preferably in the The area between the respective sectors 3a ", 3b", 3c "provided. The preferred layer structure of a carrier substrate for a

The light field 2, 2 ', 2 "according to the invention preferably comprises the following layers from the bottom to the top: a highly reflective aluminum layer, an adhesive layer, an FR4 layer, an electrical one conductive copper layer, a solder mask ("solder mask"), a protective layer.

The manufacturing method according to the invention of the LED module 1 and the LED module 1 itself make it possible to produce a lighting device having the LED module 1 and preferably an attached reflector. Since the present invention is a reduction of the

Diameter of the light field 2, 2 !, 2 "allows the LED module 1 is particularly advantageous for a luminaire optics with an attached reflector.

Claims

claims

LED module (1) for emitting mixed light, preferably white light, comprising

a light field (2; 2 '; 2 ") which is subdivided into a plurality of regions for outputting different light spectra,

wherein the regions of the light field (2; 2 '; 2 ") are areal sectors (3a, 3b, 3c; 3a ¹ , 3 ⁽ , 3c';3a", 3b ", 3c").

LED module (1) according to claim i, wherein at least two planar sectors (3a, 3b, 3c; 3a ' ₎ 3b', 3c '; 3a ", 3b", 3c ") are provided for each light spectrum.

The LED module (1) according to claim 1 or 2, wherein the outer contour of the light field (2; 2 '; 2 ") is circular.

LED module (1) according to claim 3, wherein circular sectors (3a, 3b) of the circular light field (2) for discharging at least one

3c) in the light field (2) for emitting at least one other

Light spectrum are designed.

The LED module (1) according to claim 4, wherein the circular islands (3c) are adapted to emit light from the red light spectrum.

The LED module (1) according to any one of claims 1 to 5, wherein the light field (2; 2 '; 2 ") has a diameter of 16 mm or less.

LED module (1) according to one of Claims 1 to 6, which furthermore has a light diffusion plate (4) which is at a distance from the light field (2; 2 '; 2 ") in the light emission direction of the light field (2; 2';2"). ) is arranged. LED module (1) according to claim 7, wherein the diffusing screen (4) is separated from the upper side of the light field (2; 2 '; 2 ") by a mixing chamber.

LED module (1) according to one of claims 1 to 8, wherein the light field (2; 2 '; 2 ") with the planar sectors (3a, 3b, 3c; 3a', 3b ', 3c'; 3a", 3b ", 3c") is produced by insulation and filling.

LED module (1) according to one of claims 1 to 9, wherein the planar sectors (3a, 3b, 3c; 3a ¹ , 3b ¹ , 3c ^c ; 3a ", 3b", 3c ") of the light field (2 2 '; 2 ") are separated by dams (5).

LED module according to one of claims 1 to 10, wherein the planar sectors (3a, 3b, 3c; 3a ', 3b', 3c '; 3a ", 3b", 3c ") of the light field (2; 2'; 2" ) comprise a transparent potting compound or a potting compound containing phosphor.

LED module according to one of claims 1 to 11, wherein the planar sectors (3a, 3b, 3c; 3a ', 3b', 3c '; 3a ", 3b", 3c ") at least for emitting light from the red light spectrum, Light from the blue

Light spectrum or light from a further light spectrum generated by a phosphor are designed.

LED module according to one of claims 1 to 11, wherein the planar sectors (3a, 3b, 3c, 3a ', 3b', 3c ', 3a ", 3b", 3c ") each with at least one LED (6) or a LED strand are provided.

Method for producing an LED module (1) for dispensing

Mixed light, preferably white light, comprising the steps

Generating a light field (2) which is subdivided into area sectors (3a, 3b, 3c; 3a ', 3b', 3c '; 3a ", 3b", 3c ")

Forming dams (5) which separate sectors (3a, 3b, 3c; 3a ', 3b', 3c '; 3a ", 3b", 3c ") of the light field (2; 2';2") from each other, and Fill a transparent potting compound or a

Phosphor-containing potting compound between the dams (5) of each sector (3a, 3b, 3c, 3a ', 3', 3c ', 3a ", 3b", 3c ").

Lighting device comprising at least one LED module (1) according to one of claims 1 to 13 and preferably a reflector placed on the LED module (1).