PACKAGED OPTOELECTRIC MODULE AND METHOD FOR ITS PRODUCTION

Abstract

A stable, hermetically sealed, partially optically transparent package for use to protect optoelectronic components is provided. The package has good cooling for the installed circuit elements and is as stable in relation to temperature and UV. The package has a cap with a frame made of a nitride ceramic and a glass element. The frame has an opening and the glass element hermetically closes the opening. The glass is fused onto the nitride ceramic and is fixed in contact with the nitride ceramic of the frame.

Claims

1. A cap for the package of an optoelectronic component, comprising: a frame made of a nitride ceramic, the frame has an opening; and a glass element that hermetically closes the opening, the glass element is fused onto the nitride ceramic and is fixed in contact with the nitride ceramic of the frame.

2. The cap of claim 1, wherein the glass element and the frame have interface surfaces that bear on one another with complementary fine structures along an entirety thereof.

3. The cap of claim 2, wherein the glass element is fused into the opening and is connected to an inner wall of the opening so that the inner wall encloses the glass element on a circumference of the glass element and hermetically seals a transition between the frame and the glass element.

4. The cap of claim 1, wherein the glass element further comprises an open cavity on an inner side.

5. The cap of claim 1, further comprising a direct interface between glass of the glass element and the nitride ceramic of the frame.

6. The cap of claim 1, wherein the frame comprises aluminum nitride.

7. The cap of claim 1, further comprising a contact angle between glass of the glass element and the nitride ceramic of the frame that is more than 90°.

8. The cap of claim 1, wherein the frame has a linear thermal expansion coefficient that is greater than or equal to a thermal expansion coefficient of glass of the glass element.

9. The cap of claim 1, wherein the frame has an average value of a thermal expansion coefficient in a temperature interval of from 20° C. to a glass transition temperature (T.sub.g) of glass of the glass element that is greater than or equal to an average value of a thermal expansion coefficient of the glass of the glass element.

10. The cap of claim 1, further comprising a difference between a thermal expansion coefficient of the frame and a thermal expansion coefficient of glass of the glass element that is at least Δα=0.1.Math.10.sup.−6K.sup.−1.

11. The cap of claim 10, wherein the difference is at least Δα=0.5.Math.10.sup.−6K.sup.−1.

12. The cap of claim 10, wherein the difference is at least Δα=2.Math.10.sup.−6K.sup.−1.

13. The cap of claim 1, wherein the glass element comprises glass having a bismuth content of less than 5 wt % at least where the glass element interfaces with the frame.

14. The cap of claim 1, wherein the glass element comprises glass having a bismuth content of less than 2 wt % at least where the glass element interfaces with the frame.

15. The cap of claim 1, wherein the opening has a shape selected from a group consisting of round, nonround, angular, polygonal, angular with rounded corners, and polygonal with rounded corners.

16. The cap of claim 1, wherein the frame exerts a compressive stress on the glass element.

17. The cap of claim 1, further comprising a feature selected from a group consisting of: a lateral dimension of the glass element that lies in a range of from 2 mm to 20 mm; an average thickness of the glass element that lies in a range of from 0.2 mm to 2 mm; a ratio of an average thickness of the glass element to a lateral dimension of the glass element that is less than 1/20; a wall thickness of the frame that is in a range of from 0.5 mm to 2 mm; a shoulder of the frame that is in contact with the glass element; a granularity of the nitride ceramic that has an average grain diameter in a range of from 1 to 10 μm; and a radius of rounded corners in the opening of the frame that are more than 0.05 mm.

18. An optoelectronic component, comprising: a carrier; an electronic circuit element on the carrier; and a frame made of a nitride ceramic and a glass element that hermetically closes an opening in the frame, the glass element is fused onto the nitride ceramic and is fixed in contact with the nitride ceramic of the frame, wherein the cap is on the carrier and connected thereto so that the electronic circuit element is enclosed and hermetically encapsulated in a cavity formed between the cap and the carrier, and wherein the glass element forms a translucent window to the cavity.

19. A method for producing a cap for packaging optoelectronic components, comprising: making a frame of nitride ceramic with an opening; bringing a glass preform together with the frame at the opening; and isothermally heating the glass preform and the frame so that the glass of the glass preform softens and fuses onto the frame to close the opening.

Description

BRIEF DESCRIPTION OF FIGURES

[0015] The invention will be explained in more detail below more accurately and with reference to the figures.

[0016] FIGS. 1-2 each show a sectional view of an optoelectronic component;

[0017] FIG. 3 shows a plan view of the optoelectronic component according to FIG. 1;

[0018] FIGS. 4-6 show electron microscopy images of the region of the interface between the frame and the glass element;

[0019] FIG. 7 shows the frame of the cap and a glass preform with a mold part for shaping the glass preform before the connection;

[0020] FIG. 8 shows an alternative embodiment of the arrangement of FIG. 7; and

[0021] FIG. 9 shows a continuous oven for fusing the glass element onto the frame.

DETAILED DESCRIPTION

[0022] FIG. 1 shows an optoelectronic component 1 in a sectional view. The component 1 comprises a cap 2 having a frame 5 made of a nitride ceramic, which has an opening 7, and a glass element 8 which hermetically closes the opening 7, is fused onto the nitride ceramic and is fixed in contact with the nitride ceramic of the frame 5. According to FIG. 2, the frame 5 has a shoulder 60 on its inner circumference, into which the glass element 8 can be placed, wherein the depth of the shoulder may also be configured to be less than the thickness of the glass element. Accordingly, in one embodiment, without restriction to the specific configuration of the example of FIG. 2, it is provided that the frame has a shoulder 60 or a step, onto which the glass element 8 can be placed and which is therefore in contact with the glass element 8 after the fusion.

[0023] As in the represented example of FIG. 1 and FIG. 3, it is preferred for an open cavity 11 to be formed in the cap 2 on an inner side 17 of the glass element 8. The electronic circuit element 13 then protrudes into this cavity 11.

[0024] The component 1 furthermore has a carrier 10 and at least one electronic circuit element 13 fastened on the carrier 10, the cap 2 being placed on the carrier 10 and connected thereto, so that the electronic circuit element 13 is enclosed and hermetically encapsulated in a cavity 11 formed between the cap 2 and the carrier 10. According to one preferred embodiment, the electronic circuit element 13 may be a UV light-emitting diode. Accordingly, in this case the component 1 is a packaged light-emitting diode for emitting UV light. The structure described here is advantageous particularly for UV light-emitting diodes since the efficiency of the light-emitting diodes is only low (typically 1-2%), so that the light-emitting diodes become very hot.

[0025] A good connection of the frame 5 and the glass element 8 is achieved in particular when the glass element 8 is fused into the opening 7 of the frame 5 and is connected to the inner wall 9 of the opening 7, so that the inner wall 9 of the frame 5 encloses the glass element 8 annularly and hermetically seals the transition between the frame 5 and the glass element 8. It is also possible in particular to produce the connection between the frame and the glass element without intermediate materials. Accordingly, it is provided that a direct interface 57 is formed between the glass of the glass element 8 and the nitride ceramic.

[0026] FIG. 4, FIG. 5 and FIG. 6 in this regard show electron microscopy images of the region of the interface between the frame 5 and the glass element 8 at different magnifications. As is preferred, the frame 5 of this example consists of aluminum nitride. The scale is respectively represented in the bars below the images. The granular structure of the aluminum nitride ceramic may be seen clearly. No transition region is to be seen at the interface 57. This indicates that a reaction or mixing does not take place between the nitride ceramic of the frame 5 and the glass of the glass element 8 at the interface, so that a sharp interface is formed, or the glass and the aluminum nitride ceramic are adjacent to one another without a transition. Surprisingly, it has been found that this can be influenced by means of the composition of the glass of the glass element 8, and in particular glasses containing bismuth may in this case be disadvantageous for intimate interlocking at the interface 57 between the glass element 8 and the frame 5. According to one embodiment, it is therefore also provided that the glass of the glass element has a bismuth content of less than 5 wt %, preferably less than 2 wt %, or is even free of bismuth, at least at the interface 57 with the frame 5. The figures also show that glass and nitride ceramic bear on one another along the entire interface on account of the fusion of the glass element as a result of a softening of the entire glass element. Therefore, in one embodiment, it is generally also provided that the surfaces of glass and nitride ceramic bear on one another and have a complementary fine structure along the entire interface 57 between the glass of the glass element 8 and the nitride ceramic of the frame 5. This also differentiates the interface for instance from a laser-joined connection. In the case of such a connection, the material is fused only locally, for instance along a joining line. The nitride ceramic preferably has at least a granularity with an average grain diameter in the range of from 1 to 10 μm. This leads to a surface that is rough enough to anchor the glass element firmly. On the other hand, the grains are still small enough to provide a dense composition for hermetic enclosure of the electronic circuit element or elements.

[0027] In general, without restriction to the example shown in FIG. 1 and FIG. 3, in one refinement of the optoelectronic component described here, it is provided that the carrier 10 also comprises nitride ceramic in order to achieve good heat dissipation from the electronic circuit element 13.

[0028] For a hermetic connection of the frame 5 and the glass element 8, it is in general particularly favorable for the frame to have a linear thermal expansion coefficient which is greater than the thermal expansion coefficient of the glass of the glass element 8. This applies in particular to the average value of the thermal expansion coefficient of the frame in relation to the average value of the thermal expansion coefficient of the glass element in a temperature interval of from 20° C. to the glass transition temperature T.sub.g of the glass element. The difference Δα of the thermal expansion coefficients may readily be up to Δα=7.Math.10.sup.−6K.sup.−1. Preferably, the difference is Δα<3.Math.10.sup.−6K.sup.−1. The difference of the thermal expansion coefficients assists the buildup of a compressive stress during the cooling after the melting and solidification of the glass element 8 in the frame 5. It is therefore favorable for the difference of the thermal expansion coefficients to be at least Δα=2.Math.10.sup.−6K.sup.−1, preferably at least Δα=0.5.Math.10.sup.−6K.sup.−1, most preferably at least Δα=0.1.Math.10.sup.−6K.sup.−1.

[0029] Generally, in one particularly preferred embodiment, it is also provided to this end that the frame 5 then exerts a compressive stress on the glass element 8. Surprisingly, the formation of a suitable hermetically sealed connection is possible even with approximately equal or equal thermal expansion coefficients, i.e. matched glazing. Approximately equal or substantially equal thermal expansion coefficients α in this case also include a magnitude range of up to |Δα=1.0.Math.10.sup.−6K.sup.−1|, preferably up to |Δα=0.1.Math.10.sup.−6K.sup.−1|, i.e. a difference in magnitude of the thermal expansion coefficients of the frame and the glass element up to the aforementioned value of 1.0.Math.10.sup.−6K.sup.−1, preferably up to 0.1.Math.10.sup.−6K.sup.−1. Optionally, the thermal expansion coefficient of the glass in the scope of this difference in magnitude may also be either greater or less than the thermal expansion coefficient of the frame.

[0030] In order that the compressive stress presses the glass and the nitride ceramic onto one another at the interface, it is favorable to select the glass element not to be too thin in relation to its lateral dimensions. Otherwise, the compressive stress may be reduced by resilient bending of the glass element. Lateral, or sideways, dimensions in the range of from 2 mm to 20 mm are preferred. In the case of rectangular or square glass elements, these measurements are the longest side lengths. The diagonal measurements may correspondingly be longer. The average thickness of the glass element 8 preferably lies in the range of from 0.2 mm to 2 mm. Taking these measurements into account, the ratio of the average thickness of the glass element to the lateral, or sideways, dimension, i.e. in particular to the diameter or to the longest side length, is preferably less than 1/20, preferably less than 1/15. Shapes with a ratio of more than 1 are also conceivable, for instance when the glass element is configured as a thick lens or light guide. The frame 5 preferably has a minimum thickness in order to improve the heat transport. A minimum thickness is also advantageous for building up high compressive stresses. According to one embodiment of the invention, the frame has a thickness, or wall thickness, in the range of from 0.5 mm to 2 mm. In general, without restriction to the example represented, a cap 2 according to this disclosure may have one or more of the aforementioned features in relation to the dimensions and dimension ratios.

[0031] In the example shown in FIG. 3, the opening has a square shape. The hermetic connection of the glass to the nitride ceramic is in this case generally also thereby facilitated if the opening 7 has rounded corners 14 in the case of an angular or polygonal shape. It is in this case furthermore particularly preferred for the radius of the rounded corners to be more than 0.05 mm. Advantageously, the radius is at least 0.2 mm. Without restriction to the square shape shown in FIG. 3, the opening 7 may also have round, elliptical and/or other nonround shapes i.e. including an angular or polygonal shape, particularly in order to suit the geometry or the geometrical specifications of an optoelectronic component 1.

[0032] In order to connect the cap 2 and the carrier 10 to one another in order to produce an optoelectronic component 1, soldering of the two parts is suitable. FIG. 1 represents the connection of the cap 2 and the carrier 10 by means of a metal solder 19. The solder connects well to the nitride ceramic and furthermore has a high thermal conductivity, so that a low thermal resistance is provided at the transition between the carrier 10 and the cap 2.

[0033] The cap 2 according to this disclosure may be produced by a method in which a frame 5 made of a nitride ceramic, which has an opening 7, is provided, and wherein a glass part or glass preform is brought together with the frame 5 so that the opening 7 in the frame 5 is closed, and wherein the glass preform 6 is isothermally heated together with the frame 5 so that the glass of the glass preform softens and fuses onto the frame 5.

[0034] Particularly preferably, the fusion of the glass preform to form the glass element 8 that closes the opening 7 is carried out in a continuous oven. The method steps according to preferred configurations will be explained in more detail below with reference to the purely exemplary drawings. FIG. 7 in this regard shows the frame 5 and a glass preform 6, which is intended to be fused to the frame 5 in order to form the cap 2. To this end, the frame 5 is placed onto a mold part 20 and the glass preform 6 is placed into the opening 7 of the frame 5. The upper side of the mold part 20 is used as a shaping surface for the glass preform 6. In the simplest case, the shaping surface is planar in order to form a planar outer surface of the glass element 8.

[0035] FIG. 9 shows an alternative embodiment of the arrangement shown in FIG. 8. Here, the mold part 20 is configured as a die, the die surface 22 of which protrudes into the frame 5 when the latter is placed on. The glass preform 6 is placed into the frame 5 as in the arrangement of FIG. 8. The glass preform 6 now, however, bears on the inner side on the mold part 20.

[0036] In one refinement of the method, it is provided that the fusion of the glass preform 6 to the frame 5 is carried out in a continuous oven. FIG. 9 in this regard shows a continuous oven 23 having one or more heating elements 25. The mold parts 20 with the frames 5 placed on and the glass preforms 6 placed into the openings 7 of the frames 5, in particular as shown in FIG. 7 or FIG. 8, are for example conveyed through the continuous oven 23 on a conveyor belt 27. The continuous oven may in particular comprise zones with different temperatures, temperature gradients, speeds and/or oven atmospheres.

[0037] In order also to shape the inner side 17 of the glass element 8 produced from the glass preform 6 in a controlled way, according to a further preferred configuration of the method, it is provided that a die 21 is pressed onto the glass preform 6 so that the glass yields to the pressure of the die 21 when softening and is pressed onto the wall of the opening 7. In this case, the surfaces of the glass element 8 are simultaneously shaped according to the surfaces of the die 21 and the mold part 20. It is therefore possible not only to form planar disk-shaped glass elements 8. The example shown in FIG. 1 also already shows a slightly biconvex shape. With the method, during the production of the cap 2, it is thus correspondingly possible to shape glass elements that act as optical elements, such as lenses, prisms or coupling elements, such as for instance light guides. Furthermore, the application of a pressure has a positive effect overall, but particularly when there are substantially equal thermal expansion coefficients of the glass element 8 and the frame 5, on the formation of an interlock between the glass element 8 and the frame 5.

[0038] If, as is preferably provided, the linear thermal expansion coefficient of the frame 5 is greater than the linear thermal expansion coefficient of the glass element 8, a compressive stress acting on the glass element 8 is built up during the combined cooling after falling below the glass transition temperature of the glass element, since the frame 5 contracts more strongly than the glass element 8. This compressive stress presses the nitride ceramic and the glass onto one another at the interface 57. Particularly by this mechanism, on the one hand, and the surface structures fitting together exactly due to the fusing, hermetic sealing is achieved even in the case of superphobic material pairings.

LIST OF REFERENCES

[0039]

TABLE-US-00001  1 optoelectronic component  2 cap  5 frame  6 glass preform  7 opening in 5  8 glass element 10 carrier 11 cavity 13 electronic circuit element 14 corners of 7 17 inner side of 8 19 solder 20 mold part 21 die 22 die surface 23 continuous oven 25 heating element 27 conveyor belt 57 interface between frame 5 and glass element 8 60 shoulder