DE102022121034A1 - RADIATION EMITTING COMPONENT AND METHOD FOR PRODUCING A RADIATION EMITTING COMPONENT - Google Patents

Abstract

A radiation-emitting component is specified with a carrier with a main extension plane, a radiation-emitting component with a radiation exit surface, an optical element, and at least one positioning element, the radiation-emitting component being arranged on the carrier, the positioning element being arranged on the carrier, the positioning element being a Has positioning surface which extends at an angle of greater than 0 degrees to the main extension plane of the carrier, and the positioning element is arranged on a side of the optical element facing away from the radiation-emitting component. A method for producing a radiation-emitting component is also specified.

Description

A radiation-emitting component and a method for producing a radiation-emitting component are specified.

One problem to be solved is to provide a radiation-emitting component with an efficiently arranged optical element. Another task to be solved is to specify a method with which an optical element can be arranged efficiently.

The tasks are solved by the subject matter of the independent patent claims. Advantageous refinements and further developments are specified in the subclaims.

According to at least one embodiment, the radiation-emitting component comprises a carrier with a main plane of extension. The carrier can be a mechanically supporting component of the radiation-emitting component. The carrier can be three-dimensional. For example, the carrier has a circular and/or rectangular base area. The carrier can have a main plane of extension. The main extension plane, for example, runs at least approximately parallel to a surface, for example to the base and/or to a top side, of the carrier. The carrier can in particular have a cover surface on its upper side. The cover surface is, for example, a mounting surface of the carrier. The mounting surface of the carrier runs, for example, parallel or almost parallel to the main extension plane of the carrier. Components that are arranged on the carrier can, for example, be arranged on the mounting surface of the carrier.

According to at least one embodiment, the radiation-emitting component comprises a radiation-emitting component with a radiation exit surface. The radiation-emitting component is, for example, a light-emitting diode or a laser. The fact that the radiation-emitting component has a radiation exit surface means, for example, that the radiation-emitting component emits electromagnetic radiation, which is coupled out of the radiation-emitting component at the radiation exit surface. The radiation exit surface is, for example, a radiation decoupling surface. The radiation-emitting component is set up, for example, to generate and/or emit laser radiation. Laser radiation is, for example, coherent electromagnetic radiation. In other words, the radiation-emitting component can be designed to couple out coherent electromagnetic radiation at the radiation exit surface. The radiation exit surface forms, for example, an outer surface of the radiation-emitting component.

The radiation-emitting component can be arranged on the carrier. For example, the radiation-emitting component is applied to the mounting surface of the carrier. The radiation exit surface then preferably runs perpendicular or almost perpendicular to the main extension plane of the carrier and/or to the mounting surface of the carrier.

According to at least one embodiment, the radiation-emitting component comprises an optical element. For example, the optical element is an optical lens. The optical lens has, for example, a spherical structure, a Fresnel structure, a microlens array or a diffractive optical element. The optical element can be designed to shape the electromagnetic radiation passing through the optical element. For example, the electromagnetic radiation emitted by the radiation-emitting component can be focused or scattered by the optical element. In particular, the optical element is designed to maintain coherence of the electromagnetic radiation emitted by the radiation-emitting component. For example, a phase front of the laser radiation is not affected by the optical element.

The optical element can be cuboid-shaped, for example. For example, the optical element comprises a plate. The optical element can have glass and/or plastic or be made of glass and/or plastic. In particular, the optical element can be a glass plate.

Alternatively or additionally, the optical element can be at least approximately wedge-shaped and/or trapezoidal in places. For example, at least one side surface of the optical element is trapezoidal and/or wedge-shaped. This side surface of the optical element in the radiation-emitting component preferably runs perpendicular to the main plane of extension of the carrier and perpendicular to the radiation exit surface of the radiation-emitting component. In addition, a further side surface opposite the side surface can be trapezoidal and/or wedge-shaped. For example, the side surface of the optical element and the other side surface of the optical element are congruent. One on the side surface Adjacent area of the optical element and / or an area arranged between the side surface of the optical element and the further side surface of the optical element can be approximately cuboid.

Furthermore, on a side of the optical element facing the radiation-emitting component, edge regions of the optical element arranged on the side surface and/or on the further side surface and the region of the optical element arranged between them can be flush or almost flush with one another.

The optical element is arranged, for example, on the radiation-emitting component. This can mean that the optical element is mechanically connected to the radiation-emitting component. In particular, the optical element can be arranged on the radiation exit surface of the radiation-emitting component. The optical element can adjoin the radiation exit surface. For example, the optical element borders directly on the radiation exit surface. Alternatively, a material, for example an adhesive material, can be arranged between the optical element and the radiation-emitting component, in particular between the optical element and the radiation exit surface of the radiation-emitting component.

According to at least one embodiment, the radiation-emitting component comprises at least one positioning element. The positioning element can be arranged on the carrier. The fact that the positioning element is arranged on the carrier can mean in particular that the positioning element is arranged on the mounting surface of the carrier. For example, the positioning element is applied directly to the mounting surface of the carrier.

The positioning element can have a positioning surface. For example, the positioning element comprises more than one positioning surface, in particular one further positioning surface. The positioning surface extends, for example, at a first angle of greater than 0 degrees to the main plane of extension of the carrier. The first angle at which the positioning surface extends is, for example, less than 90 degrees. In other words, the positioning surface runs, for example, transversely to the main plane of extension of the carrier. The positioning surface can extend at a first angle of greater than 30 degrees or greater than 45 degrees to the main extension plane of the carrier. The positioning surface can extend at a first angle of at most 80 degrees or at most 70 degrees to the main extension plane of the carrier.

The positioning element can be wedge-shaped. The positioning element tapers away from the carrier, for example in a direction perpendicular to the main extension plane of the carrier. A distance between the radiation-emitting component and the positioning element increases, for example, away from the carrier along a direction perpendicular to the main extension plane of the carrier.

The positioning element is arranged, for example, on a side of the optical element facing away from the radiation-emitting component.

According to at least one embodiment, the radiation-emitting component comprises a carrier with a main extension plane, a radiation-emitting component with a radiation exit surface, an optical element and at least one positioning element, wherein the radiation-emitting component is arranged on the carrier, the positioning element is arranged on the carrier, the positioning element a Positioning surface which extends at a first angle of greater than 0 degrees to the main extension plane of the carrier and the positioning element is arranged on a side of the optical element facing away from the radiation-emitting component.

The radiation-emitting component described here is based, among other things, on the idea that the optical element can be arranged or precisely positioned on the radiation exit surface of the radiation-emitting component in a simplified and cost-effective and therefore efficient manner by means of the at least one positioning element. For precise positioning of the optical element, the optical element can be applied to the positioning surface. For this purpose, the optical element can be applied to the positioning element on the side that is furthest away from the carrier. Since the positioning surface runs at an angle of greater than 0 degrees to the main extension plane, the optical element can slide down the positioning surface towards the carrier. The optical element can be passively applied to the carrier close to the radiation exit surface. In particular, the optical element can be arranged close to the radiation exit surface of the radiation-emitting component. A distance between the optical element and the radiation-emitting component can be relatively small. This allows the structure of the radiation-emitting component must be kept compact.

According to at least one embodiment of the radiation-emitting component, the positioning element has an extension parallel to the main plane of extension of the carrier, which decreases away from the carrier along a vertical direction which extends perpendicular to the main plane of extension of the carrier. A distance between the radiation-emitting component and the positioning element thus increases, for example, away from the carrier along a direction perpendicular to the main extension plane of the carrier. The size of a cross section through the positioning element in planes that extend parallel to the main extension plane of the carrier can thus decrease along the vertical direction from the carrier.

An advantage of this embodiment is that the positioning element can have a positioning surface that runs obliquely, transversely and/or obliquely to the main extension plane of the carrier, on which an optical element can slide down onto the carrier. This allows the optical element to be arranged simply and cost-effectively on the radiation-emitting component.

According to at least one embodiment of the radiation-emitting component, the positioning element has at least one further positioning surface, wherein the positioning surface runs at a first angle to the main plane of extension of the carrier and the further positioning surface runs at a second angle to the main plane of extension of the carrier and the second angle is at least 5 degrees from first angle differs. The further positioning surface thus has a further slope, which is different from a slope of the positioning surface.

The second angle can differ from the first angle by at least 5 degrees, for example by at least 10 degrees, for example by at least 20 degrees, in particular by at least 30 degrees. The second angle can, for example, be designed to be larger than the first angle. For example, the second angle is 90 degrees. The further positioning surface can therefore, for example, run perpendicular to the main extension plane of the carrier. The further positioning surface can be arranged closer to the carrier than the positioning surface.

Because the further positioning surface has a different, steeper slope than the positioning surface, a distance between the positioning element and the radiation-emitting component can be increased. As a result, deviations in the position of the positioning element relative to the radiation-emitting component can be compensated for and the optical element can be efficiently arranged on the radiation exit surface of the radiation-emitting component.

According to at least one embodiment of the radiation-emitting component, an intermediate carrier is arranged at least in places between the radiation-emitting component and the carrier. The intermediate carrier is, for example, a submount of the radiation-emitting component. The intermediate carrier borders, for example, directly on the radiation-emitting component and/or on the carrier. The intermediate carrier comprises, for example, a material with high thermal conductivity.

An advantage of this embodiment is that the intermediate carrier ensures cooling of the radiation-emitting component. A further advantage is that the radiation-emitting component and thus the radiation exit surface of the radiation-emitting component are arranged at a distance from the carrier through the intermediate carrier. As a result, the electromagnetic radiation coupled out at the radiation exit surface can radiate through the optical element in the center or almost in the center. Disturbing edge effects on the optical element can thus be reduced.

According to at least one embodiment of the radiation-emitting component, an intermediate carrier is arranged at least in places between the radiation-emitting component and the carrier, wherein the radiation-emitting component at least partially projects beyond the intermediate carrier on the side on which the radiation exit surface of the radiation-emitting component is arranged.

Because the radiation-emitting component projects beyond the intermediate carrier on the side facing the optical element, the optical element can be arranged in a simplified manner on the radiation exit surface of the radiation-emitting component.

According to at least one embodiment of the radiation-emitting component, the optical element is at least approximately cuboid-shaped. The optical element is, for example, a plate with an approximately rectangular base area.

This allows the optical element to be manufactured in a simplified and cost-effective manner.

According to at least one embodiment of the radiation-emitting component, a surface of the optical element runs parallel to the positioning surface at least in places. For example, the side of the optical element facing away from the radiation-emitting component runs at least in places approximately parallel to the positioning surface of the positioning element. For example, only the side surface of the optical element arranged in an edge region of the optical element can run parallel to the positioning surface. The edge region of the optical element is, for example, the region of the optical element that is arranged adjacent to the positioning surface. For example, the edge region of the optical element can directly adjoin the positioning surface.

As a result, precise positioning of the optical element on the radiation-emitting component can be improved.

According to at least one embodiment of the radiation-emitting component, the optical element is at least approximately cuboid-shaped with two congruent trapezoids at both ends of the cuboid. The trapezoidal prism-shaped areas of the optical element are, for example, the edge areas of the optical element.

The trapezoidal prism-shaped areas allow the optical element to be precisely positioned on the radiation exit surface of the radiation-emitting component.

According to at least one embodiment of the radiation-emitting component, at least one further positioning element is arranged on the carrier, and the further positioning element is arranged at a distance from the positioning element. The further positioning element can have the same properties as the positioning element. For example, the optical element is set up to be allowed to slide simultaneously on the positioning element and the further positioning element towards the carrier and the radiation-emitting component.

The optical element can be arranged simply and cost-effectively and efficiently on the radiation exit surface of the radiation-emitting component by the positioning element and the further positioning element.

According to at least one embodiment of the radiation-emitting component, a connecting line from the positioning element to the further positioning element runs parallel to the radiation exit surface and a distance between the positioning element and the further positioning element is greater than the extent of the radiation exit surface along the connecting line. The connecting line is in particular an imaginary connecting line. The imaginary connecting line runs, for example, along the shortest connection between the positioning element and the further positioning element. The fact that the distance between the positioning element and the further positioning element is greater than the extent of the radiation exit surface along the connecting line can mean in particular that radiation emerging from the radiation-emitting component mainly propagates in a direction other than in the direction of the positioning element and the further positioning element.

As a result, electromagnetic radiation emerging from the radiation exit surface of the radiation-emitting component is not absorbed and/or reflected by the positioning elements. In addition, the positioning elements allow the optical element to be efficiently arranged on the radiation exit surface.

According to at least one embodiment of the radiation-emitting component, an adhesive material is arranged between the optical element and the radiation-emitting component. The adhesive material can be translucent or transparent. For example, the adhesive material is translucent to the electromagnetic radiation coupled out at the radiation exit surface of the radiation-emitting component. The adhesive material is designed, for example, to wet the optical element and/or the radiation-emitting component and/or the intermediate carrier. The adhesive material includes, for example, silicone.

For example, the adhesive material is designed to couple the optical element to the radiation exit surface of the radiation-emitting component and/or to fix the optical element in the radiation-emitting component.

By wetting the optical element and/or the radiation-emitting component and/or the intermediate carrier, the optical element is erected by means of capillary forces, at least approximated to the radiation exit surface of the radiation-emitting component and/or arranged on the radiation exit surface. The optical element can therefore be passively connected to the beam The exit surface of the radiation-emitting component can be arranged.

According to at least one embodiment of the radiation-emitting component, the adhesive material completely fills a gap between the optical element and the radiation-emitting component.

This embodiment of the radiation-emitting component has, among other things, the advantage that the optical element is stably connected to the radiation exit surface of the radiation-emitting component. This allows the optical element to be arranged simply and efficiently on the radiation exit surface.

According to at least one embodiment of the radiation-emitting component, the adhesive material is translucent, in particular transparent, for the electromagnetic radiation emitted by the radiation-emitting component. The adhesive material has, for example, at least a low absorption and/or at least a low reflectivity, for example of the electromagnetic radiation emitted by the radiation-emitting component. For example, the adhesive material has a high transmission and/or a high transparency for, for example, the electromagnetic radiation emitted by the radiation-emitting component. The transmission and/or transparency can be at least 10%, for example at least 50%, for example at least 80% or in particular at least 90%.

An advantage of this embodiment is that the electromagnetic radiation emitted by the radiation-emitting component is not or only slightly absorbed and/or reflected by the adhesive material. This allows the electromagnetic radiation to radiate efficiently through the adhesive material.

According to at least one embodiment of the radiation-emitting component, the radiation-emitting component additionally comprises a frame with a recess, the frame at least partially surrounding the radiation-emitting component, and the positioning element being arranged in the recess. The fact that the frame at least partially surrounds the radiation-emitting component can mean that the frame laterally surrounds the radiation-emitting component on at least one side. For example, the frame surrounds the radiation-emitting component on more than one side. In particular, the frame can surround the radiation-emitting component laterally on three sides. The frame cannot completely laterally surround the radiation-emitting component, particularly on the side on which the radiation exit surface is arranged.

The frame can have a recess. The recess can be arranged at a distance from the radiation exit surface along a radiation direction and/or along a direction which runs parallel to the radiation exit surface. The radiation direction can in particular be the direction in which the electromagnetic radiation is coupled out of the radiation-emitting component. The recess can extend along the frame. The recess can extend at least partially through the frame along a direction that runs parallel to the radiation exit surface. For example, the recess extends completely through the frame parallel to the radiation exit surface. The area between the radiation exit surface and a surface from which radiation emerges from the radiation-emitting component during operation can be free of the frame. The positioning element can be arranged in the recess. The positioning element can be arranged downstream of the radiation exit surface in the radiation direction. Radiation emitted by the radiation-emitting component can emerge from the radiation-emitting component through the recess. A radiation direction of the radiation-emitting component can thus run parallel to the main extension plane of the radiation-emitting component.

According to at least one embodiment of the radiation-emitting component, the positioning element is designed monolithically with the frame. The positioning element is formed, for example, from the frame.

This allows the positioning element to be produced in a simplified manner and arranged on the carrier.

A method for producing a radiation-emitting component is also specified. The radiation-emitting component can preferably be produced using a method described here. In other words, all of the features disclosed for the radiation-emitting component are also disclosed for the method for producing a radiation-emitting component and vice versa.

According to at least one embodiment of the method for producing a radiation-emitting component, the method includes providing a carrier with a main extension plane, applying a radiation-emitting component with a radiation exit surface to the carrier, arranging a positioning element with a positioning surface on the carrier and positioning an optical element on the positioning element, the positioning surface extending at an angle of greater than 0 degrees to the main plane of extension of the carrier and after positioning the optical element on the positioning element, the positioning element at an angle facing away from the radiation-emitting component Side of the optical element is arranged.

According to at least one embodiment of the method for producing a radiation-emitting component, the method includes allowing the optical element to slide in the direction of the carrier on the positioning element. After positioning the optical element on the positioning element, the optical element can be precisely positioned passively on the radiation exit surface. For this purpose, the optical element can be placed on the positioning element, for example in an area of the positioning surface which is arranged at a distance from the carrier. In other words, the optical element can be positioned on the positioning element. For example, the optical element can slide down on the positioning surface by means of gravity acting on the optical element. For example, the optical element slides on the positioning element towards the carrier until the optical element is in direct contact with the carrier, at least in places. For example, the optical element can then also be in contact with the radiation exit surface. Alternatively or additionally, the optical element can be in direct contact with an adhesive material after sliding down on the positioning surface.

Because the optical element is positioned passively, the optical element can be positioned easily and cost-effectively on the radiation exit surface.

According to at least one embodiment of the method for producing a radiation-emitting component, before positioning the optical element on the positioning element, an adhesive material is applied to a region of the carrier adjacent to the radiation exit surface of the radiation-emitting component. The adhesive material can be applied, for example, between the radiation exit surface and the positioning element. In other words, the adhesive material can be applied to the carrier at a position which is arranged adjacent to the radiation exit surface. It is also possible for the adhesive material to be applied to the carrier at a position that is arranged adjacent to the intermediate carrier. For example, the adhesive material can be applied to the carrier between the connecting line between the positioning element and the further positioning element and the radiation exit surface. The adhesive material can be applied to the carrier at a point that is downstream of the radiation exit surface in the radiation direction.

An advantage of this embodiment is that the optical element can be passively arranged precisely on the radiation exit surface of the radiation-emitting component by wetting it with the adhesive material using capillary forces.

According to at least one embodiment of the method for producing a radiation-emitting component, the adhesive material is hardened after the optical element has been allowed to slide.

The optical element can thereby be stably fixed to the radiation exit surface of the radiation-emitting component.

According to at least one embodiment of the method for producing a radiation-emitting component, arranging the positioning element includes arranging a frame so that the frame surrounds the radiation-emitting component at least in places, producing a recess in the frame and producing the positioning element.

This allows the positioning element to be produced in a simplified manner and arranged on the carrier.

According to at least one embodiment of the method for producing a radiation-emitting component, the positioning element and the recess in the frame are produced in one method step. In other words, the positioning element can be created by creating the recess. For example, the recess is created in the frame. Alternatively, the frame can be produced, for example, in such a way that the frame encompasses the recess. The positioning surface of the positioning element can be a surface of the frame.

The positioning element can be created in a simplified manner.

The radiation-emitting component described here and the method for producing a radiation-emitting component described here are described below in conjunction with Aus Examples of leadership and the associated figures are explained in more detail.

1 shows a schematic top view of a radiation-emitting component according to an exemplary embodiment.

2 shows a schematic cross section through a radiation-emitting component according to an exemplary embodiment.

3 shows an optical element according to an exemplary embodiment.

The 4A and 4B show in schematic cross sections the sliding and positioning of an optical element on a positioning element according to an exemplary embodiment.

The 5A and 5B show in schematic cross sections the sliding and positioning of an optical element on a positioning element according to a further exemplary embodiment.

The 6A and 6B show in schematic cross sections the sliding and positioning of an optical element on a positioning element according to a further exemplary embodiment.

Identical, similar or identically acting elements are provided with the same reference numerals in the figures. The figures and the size relationships between the elements shown in the figures should not be considered to scale. Rather, individual elements can be shown exaggeratedly large for better display and/or for better comprehensibility.

1 shows a schematic top view of a radiation-emitting component 100 according to an exemplary embodiment. The radiation-emitting component 100 has a carrier 8 with a main plane of extension. The radiation-emitting component 100 further comprises a radiation-emitting component 6 with a radiation exit surface 9, an optical element 3 and at least one positioning element 1. The radiation-emitting component 6 is arranged on the carrier 8. The positioning element 1 is arranged on the carrier 8. The positioning element 1 is arranged on the carrier 8 at a distance from the radiation-emitting component 6. The positioning element 1 has a positioning surface 2. The positioning element 1 is arranged on a side of the optical element 3 facing away from the radiation-emitting component 6. The radiation-emitting component 100 comprises a frame 10 with a recess 14. The frame 10 at least partially surrounds the radiation-emitting component 6. For example, shown here, the frame 10 surrounds the radiation-emitting component 6 laterally on three sides. The lateral directions run parallel to the main extension plane of the carrier 8. The radiation exit surface 9 is arranged on the remaining fourth side. The frame 10 surrounds the radiation-emitting component 6 at least not completely on the side of the radiation-emitting component 6 on which the radiation exit surface 9 is arranged. The positioning element 1 is arranged in the recess 14. The optical element 3 is at least partially arranged on the positioning surface 2 in the recess 14. The optical element 3 borders on the radiation exit surface 9.

The frame 10 has a further recess 15. The further positioning element 11 is arranged in the further recess 15. An imaginary connecting line along the shortest connection between the positioning element 1 and the further positioning element 11 runs parallel to the radiation exit surface 9. A distance between the positioning element 1 and the further positioning element 11 can be larger than the extent of the radiation exit surface 9 of the radiation-emitting component 6 along the connecting line.

The radiation-emitting component 6 is applied to an intermediate carrier 7. The radiation-emitting component 6 projects at least partially beyond the intermediate carrier 7 on the side on which the radiation exit surface 9 of the radiation-emitting component 6 is arranged.

2 shows a schematic cross section through an in 1 described radiation-emitting component 100 according to an exemplary embodiment. The positioning surface 2 of the positioning element 1 extends at a first angle α of greater than 0 degrees to the main extension plane of the carrier 8. The first angle α can be smaller than 90 degrees. The positioning surface 2 can thus run transversely to the main extension plane and/or to the mounting surface 16 of the carrier 8. The optical element 3 borders directly on the radiation-emitting component 6. The frame 10 extends on at least two sides of the recess 14. The frame 10, for example, borders directly on the positioning element 1. Alternatively, the positioning element 1 can be formed from the frame 10. The positioning element 1 can be designed monolithically with the frame 10. Optionally, the two can be in 2 Parts of the frame 10 shown can be connected to one another. For example, surrounds the frame 10 has the recess 14 laterally on three sides.

3 shows an optical element 3 according to an exemplary embodiment. The optical element 3 is arranged, for example, in a radiation-emitting component 100 according to an exemplary embodiment. Furthermore, the optical element 3 can be set up to slide down the positioning surface 2. At least one area of the optical element 3 is at least approximately cuboid. For example, the optical element 3 can be at least approximately cuboid-shaped. The side of the optical element 3 facing the radiation-emitting component 6 is, for example, flat. In other words, different areas of the optical element 3 are flush with one another on the side facing the radiation-emitting component 6. The optical element 3 can be at least approximately wedge-shaped and/or trapezoidal in places. Edge regions of the optical element 3 have, for example, approximately the shape of a trapezoidal prism.

The 4A and 4B show in schematic cross sections the sliding and positioning of an optical element 3 by means of a positioning element 1 according to an exemplary embodiment.

4A shows method steps in a method for producing a radiation-emitting component 100 according to an exemplary embodiment. The the 4A Previous method steps include providing the carrier 8 with the main extension plane, applying the radiation-emitting component 6 with the radiation exit surface 9 to the carrier 8, applying an adhesive material 5 to the carrier 8 at the radiation exit surface 9, arranging the positioning element 1 with the positioning surface 2 on the carrier 8 and positioning the optical element 3 on the positioning element 1. The radiation-emitting component 6 and the positioning element 1 are arranged at a distance on the carrier 8. The adhesive material 5 is applied to the carrier 8, for example, adjacent to the radiation exit surface 9 of the radiation-emitting component 6. In other words, the adhesive material 5 can be applied to an area of the carrier 8 adjacent to the radiation exit surface 9 of the radiation-emitting component 6. The adhesive material 5 is, for example, translucent or transparent. In particular, the adhesive material can be translucent or transparent to the electromagnetic radiation emitted by the radiation-emitting component 6. For example, the adhesive material 5 is silicone or the adhesive material 5 includes silicone. The optical element here is, for example, the in 3 optical element 3 shown.

4B shows a radiation-emitting component 100 according to an embodiment. Based on the in 4A In the method steps shown, the optical element 3 slides on the positioning surface 2 of the positioning element 1 in the direction of the carrier and towards the radiation-emitting component 6. The radiation-emitting component 6 is wetted by the adhesive material 5. The adhesive material can completely fill a gap between the optical element 3 and the radiation-emitting component 6. For example, the adhesive material 5 is arranged in a space between the optical element 3 and the intermediate carrier 7, for example the adhesive material 5 completely fills the space between the optical element 3 and the intermediate carrier 7. The adhesive material 5 is arranged, for example, by means of capillary forces in the space between the optical element 3 and the intermediate carrier 7 and/or the radiation-emitting component 6. The side of the optical element 3 facing away from the radiation-emitting component 6 can be in direct contact with the positioning surface 2 of the positioning element 1 in places.

The 5A and 5B show in schematic cross sections the sliding and positioning of an optical element 3 by means of a positioning element 1 according to an exemplary embodiment.

5A shows method steps in a method for producing a radiation-emitting component 100 according to an exemplary embodiment, which differs from those in 4A The method steps shown differ in that the optical element 3 is approximately cuboid. When positioning the optical element 3 on the positioning surface 2 of the positioning element 1, the side of the optical element 3 facing away from the radiation-emitting component 6 runs almost parallel to the positioning surface 2.

5B shows a radiation-emitting component 100 according to an embodiment. Based on the in 5A In the method steps shown, the approximately cuboid-shaped optical element 3 slides on the positioning surface 2 of the positioning element 1 in the direction of the carrier 8 and the radiation-emitting component 6. The optical element 3 is then, for example, in direct contact with the Adhesive material 5. The optical element 3 and/or the intermediate carrier 7 and/or the radiation-emitting component 6 is wetted by the adhesive material 5. The optical element 3 is erected, for example by means of capillary forces, through the adhesive material 5 in the space between the optical element 3 and the intermediate carrier 7 and/or the radiation-emitting component 6 and arranged on the radiation-emitting component 6. The side of the optical element 3 facing away from the radiation-emitting component 6 does not run parallel to the positioning surface 2 in the erected state of the optical element 3, for example; in particular, the side of the optical element 3 facing away from the radiation-emitting component 6 can run perpendicular or almost perpendicular to the main extension plane of the carrier 8.

The 6A and 6B show in schematic cross sections the sliding and positioning of an optical element 3 by means of a positioning element 1 according to an exemplary embodiment.

6A shows method steps in a method for producing a radiation-emitting component 100 according to an exemplary embodiment, which differs from those in 5A The method steps shown differ in that a positioning element 1 with a positioning surface 2 and a further positioning surface 12 is arranged on the carrier. The positioning surface 2 runs at a first angle α to the main extension plane of the carrier 8. The further positioning surface 12 runs at a second angle β to the main extension plane of the carrier 8. The second angle β can deviate from the first angle α by at least 5 degrees. The second angle β is, for example, shown here, 90 degrees. In other words, the further positioning surface 12 runs perpendicular to the main extension plane of the carrier 8.

6B shows a radiation-emitting component 100 according to one embodiment. Based on the in 6A In the method steps shown, the optical element 3 slides on the positioning surface 2 of the positioning element 1 in the direction of the carrier 8 and the radiation-emitting component 6. The in 6B Radiation emitting component 100 shown differs from that in 5B radiation-emitting component 100 shown in the sense that the positioning element 1 has the positioning surface 2 and the further positioning surface 12. The optical element 3 is erected, for example by means of capillary forces, through the adhesive material 5 in the space between the optical element 3 and the intermediate carrier 7 and/or the radiation-emitting component 6 and arranged on the radiation-emitting component 6. The optical element 3 is then arranged, for example, at a distance from the positioning element 1 on the radiation-emitting component 6. Alternatively, the optical element 3 borders, for example, only on the further positioning surface 12 of the positioning element 1.

The features and exemplary embodiments described in connection with the figures can be combined with one another according to further exemplary embodiments, even if not all combinations are explicitly described. Furthermore, the exemplary embodiments described in connection with the figures can alternatively or additionally have further features according to the description in the general part.

The invention is not limited to these by the description based on the exemplary embodiments. Rather, the invention encompasses every new feature and every combination of features, which in particular includes every combination of features in the patent claims, even if this feature or this combination itself is not explicitly stated in the patent claims or exemplary embodiments.

Reference symbol list

1

Positioning element

2

Positioning surface

3

optical element

α

first angle

5

Adhesive material

6

radiation-emitting component

7

Intermediate carrier

8th

carrier

9

Radiation exit surface

10

Frame

11

another positioning element

12

another positioning surface

β

second angle

14

recess

15

further recess

16

Mounting surface

100

radiation-emitting component

Claims (19)

Radiation-emitting component (100). - a carrier (8) with a main extension plane, - a radiation-emitting component (6) with a radiation exit surface (9), - an optical element (3), and - at least one positioning element (1), wherein - the radiation-emitting component (6) is arranged on the carrier (8), - the positioning element (1) is arranged on the carrier (8), - the positioning element (1) has a positioning surface (2) which extends at a first angle (α) of greater than 0 degrees to the main extension plane of the carrier (8), and - The positioning element (1) is arranged on a side of the optical element (3) facing away from the radiation-emitting component (6). Radiation-emitting component (100) according to the preceding claim, wherein the positioning element (1) has an extension parallel to the main plane of extension of the carrier (8), which extends from the carrier (8) along a vertical direction which extends perpendicular to the main plane of extension of the carrier (8). ) decreases away. Radiation-emitting component (100) according to one of the preceding claims, in which - the positioning element (1) has at least one further positioning surface (12), the positioning surface (2) extending at a first angle (α) to the main extension plane of the carrier (8) and the further positioning surface (12) at a second angle (β) runs to the main extension plane of the carrier (8), and - the second angle (β) deviates from the first angle (α) by at least 5 degrees. Radiation-emitting component (100) according to one of the preceding claims, in which an intermediate carrier (7) is arranged at least in places between the radiation-emitting component (6) and the carrier (8), the radiation-emitting component (6) holding the intermediate carrier (7) on the Side on which the radiation exit surface (9) of the radiation-emitting component (6) is arranged, at least partially projects beyond. Radiation-emitting component (100) according to one of the preceding claims, in which the optical element (3) is at least approximately cuboid-shaped. Radiation-emitting component (100) according to one of the preceding claims, in which a surface of the optical element (3) runs parallel to the positioning surface (2) at least in places. Radiation-emitting component (100) according to one of the preceding claims, in which the optical element (3) is at least approximately cuboid-shaped with two congruent trapezoids at both ends of the cuboid. Radiation-emitting component (100) according to one of the preceding claims, wherein at least one further positioning element (11) is arranged on the carrier, and the further positioning element (11) is arranged at a distance from the positioning element (1). Radiation-emitting component (100) according to the preceding claim, wherein a connecting line from the positioning element (1) to the further positioning element (11) runs parallel to the radiation exit surface (9), and a distance between the positioning element (1) and the further positioning element (11 ) is larger than the extent of the radiation exit surface (9) along the connecting line. Radiation-emitting component (100) according to one of the preceding claims, in which an adhesive material (5) is arranged between the optical element (3) and the radiation-emitting component (6). Radiation-emitting component (100) according to the preceding claim, in which the adhesive material (5) completely fills a gap between the optical element (3) and the radiation-emitting component (6). Radiation-emitting component (100) according to one of Claims 10 until 11 , in which the adhesive material (5) is translucent to the electromagnetic radiation emitted by the radiation-emitting component (6). Radiation-emitting component (100) according to one of the preceding claims, additionally comprising: - a frame (10) with a recess (14), whereby - the frame (10) at least partially surrounds the radiation-emitting component (6), and - The positioning element (1) is arranged in the recess (14). Radiation-emitting component (100) according to one of the preceding claims, in which the Posi tioning element (1) is designed monolithically with the frame (10). Method for producing a radiation-emitting component (100), comprising the following steps: - Providing a carrier (8) with a main extension plane, - applying a radiation-emitting component (6) with a radiation exit surface (9) to the carrier (8), - Arranging a positioning element (1) with a positioning surface (2) on the carrier (8), and - Positioning an optical element (3) on the positioning element (1), whereby - the positioning surface (2) extends at a first angle (α) of greater than 0 degrees to the main extension plane of the carrier (8), and - After positioning the optical element on the positioning element, the positioning element (1) is arranged on a side of the optical element (3) facing away from the radiation-emitting component (6). Method for producing a radiation-emitting component (100) according to the preceding claim, comprising allowing the optical element (3) to slide in the direction of the carrier (8) on the positioning element (1). Method for producing a radiation-emitting component (100) according to one of Claims 15 until 16 , wherein before positioning the optical element (3) on the positioning element (1), an adhesive material (5) is applied to an area of the carrier (8) adjacent to the radiation exit surface (9) of the radiation-emitting component (6). Method for producing a radiation-emitting component (100) according to one of Claims 15 until 17 , wherein arranging the positioning element (1) comprises the following steps: - Arranging a frame (10) so that the frame (10) surrounds the radiation-emitting component (6) at least in places, - Creating a recess (14) in the frame (10 ), and - generating the positioning element (1). Method for producing a radiation-emitting component (100) according to the preceding claim, wherein the positioning element (1) and the recess (14) in the frame (10) are produced in one method step.

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