EP2682673A2 - LED light reflector and light - Google Patents

Abstract

The reflector (6) has LEDs (2) arranged in rows one behind the other in a longitudinal direction. A longitudinally extending channel-shaped bottom portion (7) is formed with multiple holes (10, 11). A pair of longitudinally extending side walls (8a, 8b) projects transversely from outer edges (8c) of the bottom portion and diverges away from the bottom portion. The side walls are provided with the outer edges deflectable elastically transversely towards each other. An upper area (8d) of the side walls is folded in an outward direction into a plane (E) parallel to the bottom portion.

Description

The invention relates to an LED luminous reflector, in particular for a luminaire with light emitting diodes sequentially arranged in a longitudinal direction. The invention further relates to a luminaire having a receiving profile for lighting means, in particular for LED strips, with a arranged in the interior of the receiving profile mounting surface on the lined in a longitudinal direction of light bulbs, especially LEDs, between opposing wall areas and with respect to a through the upper edges of the Wall openings formed areas are arranged, wherein the interior of the receiving profile of the mounting surface in the direction of the opening is widening and the opposite wall portions at the opening near the end each have at least one directed to the interior, in particular over the entire length of the receiving profile extending projection.

LED luminaire reflectors are generally known in the art and are used, for example, in LED luminaires, that is to say luminaires in which the luminous means are formed from LEDs, to form the light emission characteristic, in particular frequently the aperture angle of the light cone emitted by LEDs is large and thus beam-forming reflectors can be used when smaller beam or generally other radiation characteristics are desired than those originally given with a light emitting diode.

In this case, such arrangements of light-emitting diodes are known in the prior art, in which the individual light-emitting diodes in a longitudinal direction are arranged on a rigid or more often on a flexible board in a row behind the other.

Such LED strips or LED strips are often used as a preconfigured component in luminaires, wherein for shaping the Lichtabstrahlcharakteristik of each individual light-emitting diode according to prior art every single light-emitting diode receives its own reflector body, for which it is to be arranged around the light emitting diode around, optionally with the rigid or flexible board is to connect. For such a connection, for example special reflector fittings can be provided, which are connected to the circuit board surrounding the LED in order to grasp such a reflector.

Obviously, luminaires with such LED strips or LED strips and the previously known individual reflector arrays are expensive and require a large number of equal handling steps in the production, since sometimes several tens or even several hundred light emitting diodes of a single LED strip or LED strip within a Luminaire with such an LED strip or band is to be provided with reflectors.

It is therefore the object of the invention to provide an LED luminaire reflector, which is easy to handle especially in connection with luminaires, in which in a longitudinal direction next to each other lined up light bulbs, LED strips or LED strips are used and enables cost-effective production.

Particularly preferably, it is also an object of the invention is a luminaire of the type mentioned, for example, from the utility model DE 20 2011 104 303 the same applicant is known to develop by means of an LED luminaire reflector, which solves the above object.

The object is achieved according to the invention with an LED luminaire reflector, which is channel-shaped in a longitudinal direction, with a recesses having bottom portion and two opposing, upstanding from the bottom area, diverging Side walls whose upper edges in a direction perpendicular to the longitudinal extension are resiliently movable towards each other. Diverging is understood to mean that the distance of the side walls from one another increases from below (bottom area) upwards. Directional information is set in the sense of the invention in relation to an upward accepted light emission.

Such an LED luminaire reflector has the advantage that it has, according to its length, which is present in said longitudinal direction, a plurality of recesses corresponding to a given Repetiermaß, thus according to the invention, a single LED luminaire reflector for a plurality of multiple LEDs simultaneously Can use, which offers particular advantages if in a light, as mentioned above, several light emitting diodes are used, which are also strung in an equidistant distance from one another in a longitudinal direction. Therefore, such an LED luminaire reflector with the mentioned LED strips or LED strips can be used with particular preference.

Therefore, according to the invention eliminates the need to equip each individual LED of such a lamp with a single separate and separate reflector, but there is the possibility to use a single or only a few inventive channel-shaped LED luminous reflectors in a corresponding light, the same time as a reflector for several, preferably all light-emitting diodes of this light is used.

Thus, according to the invention with the described LED luminaire reflector and a lamp can be formed, with the features of the aforementioned type, which further includes such a channel-shaped LED luminaire reflector in its interior of the receiving profile, it may then be provided according to the invention that this luminaire reflector in the receiving profile is fixed by a clamping operative connection between the projections and the resilient upper edges of the LED luminaire reflector.

Such an attachment according to the invention is advantageously achieved in that both the interior of the receiving profile in the direction of the opening is formed widening, as is the case with the luminaire reflector by the diverging side walls, which causes such a luminaire reflector according to the invention with against the spring force acting on each other to moving side walls after insertion into a lamp with such a prescribed receiving profile tends to according to the spring force to push apart the upper edges of the diverging side walls, that is to increase the distance between the edges, and thereby exerts a force on the interior of the receiving profile, which, as described, in turn is widening in the direction of the opening. This results in an effective force component in the direction of the opening, through which a luminaire reflector according to the invention automatically in the direction of the opening, that is, in principle pushed out of the interior of the receiving profile until the upper edges of the diverging side walls of such a reflector according to the invention to the named respective Projecting projection on the end of the opposite wall portion of the receiving profile near the opening and thereby defined in the position and the reflector is fixed in the receiving profile.

An inventive LED luminaire reflector and a lamp according to the invention of the aforementioned type in connection with such a luminaire reflector thus have in common the particular advantage that it requires no special fastening measures to attach the LED luminaire reflector in the lamp according to the invention.

Rather, a luminaire reflector according to the invention need only be pressed from above into the interior of the receiving profile, for which first the diverging side walls, in particular their upper edges, contact the abovementioned projections during insertion, through which projections the diverging side walls are moved toward one another and after passing the projections in Insertion direction behind the projections, the distance of the diverging side walls or their upper edges in turn increases and thus engage behind the projections in the insertion direction.

It is also considered to be advantageous that a reflector of this type described in connection with a lamp of the type described in the direction of longitudinal extension direction is basically displaced so that alignment of the individual recesses in the reflector relative to the LEDs or other electronic components comparatively easy can be done without the need for the solution of other fasteners. Furthermore, it is advantageous that in principle all recesses within an LED luminaire reflector according to the invention are simultaneously optimally positioned relative to one another and to the corresponding light-emitting diodes or also other electronic components. It is also advantageous that such a reflector can be shortened in length without further notice.

In one possible embodiment of an LED luminaire reflector, it can be provided that the two side walls mentioned above are symmetrical to one another, wherein this symmetry can be understood in particular with respect to a center plane which is oriented parallel to the longitudinal direction and centrally to the recesses, in particular perpendicular to the bottom area, wherein a mirror symmetry can exist to this center plane.

Such an embodiment has the advantage that the emitted light cone of a corresponding luminaire with such an LED luminaire reflector substantially corresponds to a band of light whose opening angle is designed to be symmetrical about the light sources in the longitudinal direction, given by the LEDs.

In order to be able to set the radiation characteristic, in particular to be able to set the opening angle as desired and as required, it may be provided in a development of this embodiment that an upper region of each side wall is folded outwards. Such a folding can, for example, take place such that the folded upper area lies in a plane parallel to the floor area. When viewed from above onto such a reflector, a light exit slot which is more or less tapered in relation to the maximum possible width, depending on the width of the folded region, accordingly results.

In an exemplary development, it may be provided here that the outwardly folded region of each side wall has a width perpendicular to the direction of longitudinal extension which corresponds to 15 to 40%, preferably 20 to 30% of the height of the folded region above the bottom region. For example, the embodiment may also be such that the sum of the widths of the two folded regions of both side walls corresponds to the width of the bottom region.

In this embodiment, or other embodiments, it may be provided that the side walls of the LED luminaire reflector, which extend between the bottom portion and the upper folded portion, are completely non-contact with the inner wall portions of a lamp of the type described above. A contact between Reflector and luminaire or their recording profile thus results in this case only at the outer edges of the reflector.

In another embodiment, however, it may also be provided that the side walls, at least in regions, preferably over the entire length and over the entire height of each side wall above the bottom area have an outer shape which is adapted to the inner shape of a channel-shaped receiving profile of a lamp into which the LED reflector can be used.

After insertion is given due to the adaptation of these aforementioned parts to each other not only a frictional connection according to the above-described type but also a positive connection between the exterior of the diverging side walls of the LED luminaire reflector and the interior of the receiving profile.

On the one hand, this additionally stabilizes the position of the LED luminaire reflector in one luminaire, and on the other hand, the reflector can also be thermally better coupled to the receiving profile due to an enlarged contact surface between the LED luminaire reflector and the receiving profile, thus taking on additional cooling tasks in addition to its reflection tasks ,

The adaptation between the exterior of the diverging side walls of the LED luminaire reflector and the interior of the aforementioned channel-shaped receiving profile of a lamp can be made such that the contours of both components in a cross section perpendicular longitudinal direction at least partially preferably completely, based on the height of the side walls of the LED Luminaire reflectors above the floor area are the same.

In another embodiment, it can also be provided that both side walls of the LED luminaire reflector according to the invention are asymmetrical to one another. Such an asymmetry can be given, for example, with respect to a center plane parallel to the direction of longitudinal extent and centered to the recesses in the bottom area, in particular to a center plane which is oriented perpendicular to the floor area.

Such an asymmetry here has the advantage that, in a corresponding manner, the radiation profile can be configured asymmetrically to a line in which the individual light-emitting diodes are lined up as light sources. For example, this opens up the possibility of positioning luminaires according to the invention symmetrically in a room and, independently of this object symmetry thus created, to generate deviating light fans.

In accordance with the invention, asymmetries between the two side walls of the LED luminaire reflector according to the invention can result in various constructive ways and manners which can also be combined with one another.

Thus, it may be provided, for example, that one of the side walls to the above-mentioned center plane has a smaller distance perpendicular to the longitudinal direction than the other side wall.

Likewise, one of the side walls occupy a different angle relative to the bottom portion than the other side wall or at a curvature of the side walls in section perpendicular to the longitudinal direction of a different curvature or have a different radius of curvature. This can mean that the centers of the respective curvature to the center plane mentioned above have different distances.

It can also be provided that only one of the two side walls is folded outwardly in an upper region around a fold line lying in the longitudinal direction of extension. Such a folding can be carried out as in the previously described embodiment such that the folded region lies in a plane parallel to the plane of the bottom region, or else such that the planes intersect one another.

With all of the aforementioned various embodiments, a development can be combined, in which the recesses present in the longitudinal direction in the bottom region alternately have different shapes, in particular recesses with round and rectangular cross-section alternately follow one another.

In addition to an original appearance of such a luminaire reflector can be effected thereby that the recesses of a first shape, for example, those with a rectangular cross-section each associated with a light-emitting diode, in particular these surround and the recesses of a second shape, in particular with a round cross-section of other components, e.g. each associated with another electronic component, in particular surrounds this other electronic component.

Thus, on the one hand be defined by the recess of a mold, for example, the rectangular shape, the light exit opening for the respective light emitting diode, wherein the other recess may be provided to the cooling of either a arranged in the recess member or arranged below the reflector components improve. For example, this component can be a constant current source, which can be assigned to a respective light-emitting diode.

Of course, there is also the possibility of the recesses in the bottom region of an LED luminaire reflector according to the invention all in the same Form to design, which may be provided as in the previous embodiment, even with a same shape design, with a following row in the first recess to surround a light emitting diode and to surround a subsequent recess an electronic, for example, to be cooled component.

Another embodiment may also provide that recesses are provided only to provide light passage openings for the surrounded by a recess or covered by the recess LED to create and their emission characteristics.

Regardless of whether in a luminaire reflector according to the invention exclusively only round recesses are present or alternately recesses of different shapes, at least one of which corresponds to a round cross-sectional shape, it may be provided that recesses are formed with such a circular cross-sectional shape such that they each a lying below the bottom portion, a respective recess center axis (perpendicular to the longitudinal direction and in particular perpendicular to the bottom area) surrounding wall, it may be provided, for example, that such a recess surrounding the center axis wall is issued, for example, from the level of the bottom area down to Example through a forming process such as deep drawing.

Here it can be provided in a continuation of this embodiment, that a respective lying below the bottom region, a respective recess center axis surrounding wall is rotationally symmetrical about this recess center axis, in particular dome-shaped.

The arrangement of a luminaire reflector according to the invention can be independent of the aforementioned embodiments within a luminaire according to the invention such that the plane of the bottom region within which a respective recess is provided is arranged within a luminaire according to the invention in the plane of the surface of an LED or even below it, Thus, therefore, the idealized punk-shaped light source of an LED is within the recess or even easily through this into the interior of the trough-shaped reflector passes, or such that the bottom of a luminaire reflector according to the invention is located above a LED of the luminaire after mounting in a luminaire, preferably even in one embodiment with a lying below the bottom portion surrounding the Ausnehmungsachse wall region, the lower edge of this wall portion above the light emitting diode is arranged ,

In a development that is possible for all embodiments, it can additionally be provided that the interior of the receiving profile of a lamp according to the invention is encapsulated with an at least translucent, preferably transparent encapsulant. Such a casting may e.g. up to or over the aforementioned projections or even up to the top of the receiving profile. In such an embodiment, the LED luminaire reflector is particularly preferably embedded in the potting compound, in particular thus thus enclosed on all sides by the potting compound.

A potted embodiment has the advantage that a luminaire according to the invention can fulfill a high IP protection class, e.g. IP68. The potting compound may e.g. be formed by a transparent polyurethane plastic. In a further preferred embodiment of the potting can be made such that the surface of the potting compound in the solidified state has a curvature to the outside, that is outwardly convex.

• Figuren 1 einen erfindungsgemäßen LED-Leuchtenreflektor mit symmetrischen Seitenwänden in Verbindung mit einer Leuchte
• Figur 2 einen erfindungsgemäßen asymmetrischen LED-Leuchtenreflektor in Verbindung mit einer Leuchte
• Figur 3 einen erfindungsgemäßen symmetrischen LED-Leuchtenreflektor mit einer Leuchte, bei dem unterhalb des Bodenbereiches des Reflektors eine rotationssymmetrische die Ausnehmungsmittenachse umgebene Wand vorgesehen ist.

Embodiments of the invention are illustrated in the following figures. Show it:

• FIGS. 1 an inventive LED luminaire reflector with symmetrical side walls in conjunction with a lamp
• FIG. 2 an asymmetric LED luminaire reflector according to the invention in conjunction with a lamp
• FIG. 3 a symmetrical LED luminaire reflector according to the invention with a lamp in which below the bottom portion of the reflector a rotationally symmetrical the recess center axis surrounded wall is provided.

The FIG. 1 shows a first possible inventive embodiment of a luminaire reflector according to the invention as well as a lamp in which such a luminaire reflector is used.

Such a luminaire may be, in particular, such an embodiment, as it is fundamentally derived from the German utility model DE 20 2011 104 303 is known. Such a luminaire has a receiving profile 1 for illuminants, such as here for example for LED strips with a plurality of LEDs 2, which are lined up in a longitudinal direction (here perpendicular to the paper plane in the sectional view) in a predetermined Repetierabstand, so that accordingly in the Sectional view, only the lying in section light emitting diode 2 can be seen, the perspective view and the top view, however, the multiple light-emitting diodes 2 show.

These light-emitting diodes 2 are arranged on a mounting surface 3 of the receiving profile 1, which here forms a base in the interior of the trough-shaped recording profile. This receiving profile has opposing wall portions 4a and 4b which extend in the direction from the mounting surface 3 to the opening provided between the outer edges of these opposed wall portions 4a and 4b.

In this opening region, that is close to the upper end of the opposing wall regions, here in each of the wall regions a projection 5 directed towards the interior can be seen, which slightly reduces the maximum opening cross section between the opposing wall regions and thus leads to an undercut opening. Here it can be provided that the respective projections 5 extend over the entire longitudinal extension of the receiving profile or that alternatively a plurality of point or line segment-shaped projections of this type can be provided.

This first embodiment further shows that an inventive LED luminaire reflector 6 is arranged in the luminaire, which is channel-shaped in the same direction of longitudinal extension as the luminaire and has a bottom region 7 with a plurality of recesses 10, 11 and two opposing, diverging from the bottom region Side walls 8a and 8b, the upper edges 8c in a direction perpendicular to the longitudinal extension are resiliently movable towards each other.

It is thus possible according to the invention, according to the arrow 9 of FIG. 1 to insert a luminaire reflector according to the invention in the arrow direction in the opening of the receiving profile, whereby the diverging side walls or their upper edges against the acting spring force are moved toward each other by an interaction between the projections 5 and the edges 8c of the luminaire reflector and after passing the projections 5 in the Insertion direction of the arrow 9 is increased by the spring force of the distance between the edges and they are thus secured in a clamping manner behind the projections.

In this case, is split by the outward force exerted by the edges 8c of the reflector on the diverging inner walls 4a and 4b, also in a force component, which is opposite to the insertion direction of the arrow 9, so that the reflector according to the invention automatically by this force component is fixed in its position.

Is recognizable in the FIG. 1 , In particular in the perspective view and in the plan view, that a recess 10 of the LED luminaire reflector with a first shape, namely a rectangular cross-section surrounds a light emitting diode 2, wherein a recess 11, here may be provided with a round cross-sectional shape, openings to better cool on the LED strip or LED strip arranged other components, such as constant current sources. It may also be provided here that such a recess 11, in particular with a round cross-sectional shape, directly surrounds particularly heat-susceptible electronic components 12. In addition to in the FIG. 1 shown responsive optics, which is evident by the alternating different cross-sectional shapes, results so compared to conventional reflectors, which are formed only lichtstrahlformend also the ability to positively influence the cooling of the electronic components of an LED strip or a LED strip.

The FIG. 1 further shows, in particular in the sectional view, that the side walls of the LED luminaire reflector 8a and 8b are mirror-symmetrical to a plane E, which is shown by the dashed line and perpendicular to the plane in the direction of the longitudinal direction and perpendicular to the mounting surface 3 of the receiving profile or is also perpendicular to the bottom portion 7 of the reflector.

In contrast, the shows FIG. 2 a modified embodiment in which the side walls 8b and 8a of the LED luminaire reflector are asymmetrically shaped to the same plane E. In the present case, the asymmetry results, for example, from the fact that one of the side walls 8a is folded outward around a fold line in an upper region 8d. It is so, based on the idealized as a punctiform light sources of LEDs produces an asymmetric emission, in which the light fan generated in the present case is shifted in relation to its intensity maximum in the direction above the plane shown E, characterized in that in FIG. 2 shown side wall portion 8a to the plane includes a smaller angle than the side wall 8b.

The FIG. 2 shows that the folded upper portion of the side wall 8a lies in a plane which intersects the plane in which the bottom portion 7 of the reflector is arranged.

The opposite shows the FIG. 1 in that the side walls 8a and 8b there have upper regions 8d which are folded so far that these regions lie substantially in a plane parallel to the plane of the bottom region 7. In particular, by the width of the folded upper portions 8g, the opening width of the reflector between the side walls 8a and 8b can be adjusted.

Also the FIG. 2 shows in accordance with the FIG. 1 in that, in such an asymmetrical configuration of the wall regions 8a and 8b, recesses 10 and 11 may be provided in the bottom region of the reflector, which, as in the case of FIG FIG. 1 may have different cross-sectional shapes, wherein the recesses of a cross-sectional shape, in particular here the rectangular cross-sectional shape can be assigned in each case a light-emitting diode 2.

Here is both the execution in the FIG. 1 as well as the FIG. 2 such that the bottom region 7, which comprises the recesses, is arranged in the plane of the component surface or even slightly below the component surface of a light-emitting diode 2, that is to say that the light-emitting diode 2 lies at least in its associated recess 10, possibly even with its upper surface through the recess into the interior of the channel-shaped reflector enters.

Compared to these above-described embodiments shows the FIG. 3 a luminaire with essentially exactly the same characteristics as the FIGS. 1 and 2 as well as a reflector of a symmetrical design according to the invention around the aforementioned E level, wherein it is provided in this embodiment that the two side wall portions 8a and 8b of the channel-shaped LED lights reflector, which are arranged above the bottom portion 7 (parallel to the mounting surface 3) , Not only with their outer edges 8c engage behind the respective projections 5 of the receiving profile, but at the same time the outside of these side walls 8a and 8b in the contour is adapted to the interior of the opening towards widening wall portions 4a and 4b of the receiving profile, so that thereby results in a positive connection, which leads to a large contact surface between the receiving profile and reflector, so that here the reflector can also be used for heat dissipation.

In this embodiment, the plane of the bottom region 7 of the reflector according to the invention is arranged clearly above the surface of a light-emitting diode 2, wherein a rotationally symmetrical wall 13 is arranged around a recess center axis A below the bottom region 7 lower end continues to lie above the surface of the LED 2. This wall 13, which surrounds axis A rotationally symmetrically, is in this embodiment according to the FIG. 3 dome-shaped, with a circular opening.

The execution of FIG. 3 has here only recesses 10 in the plane of the bottom portion 7 of a reflector, which are each associated with a light emitting diode 2, which is located above such a light emitting diode and surrounding the optical radiation axis.

Regardless of the various constructive embodiments of the inventive luminous reflectors and their associated optical appearance, all embodiments have the invention essential advantage that this secured by a snap-in process and thus caused clamping action between the upper edges 8c and the projections 5 in a lamp of the type described can be, without this requires further attachment measures such as a screw, bonding or other type.

Claims (13)

LED luminaire reflector (6), in particular for a luminaire with light emitting diodes (2) arranged one behind the other in a longitudinal direction, characterized in that it is channel-shaped in a longitudinal direction with a bottom region (7) having recesses (10, 11) and two opposite ones rising from the bottom region (7), diverging side walls (8a, 8b) whose upper edges (8c) in a direction perpendicular to the longitudinal extension are resiliently movable towards each other. LED luminaire reflector according to claim 1, characterized in that both side walls (8a, 8b) are symmetrical to each other, in particular mirror-symmetrical with respect to a central plane (E) parallel to the longitudinal direction and central to the recesses (10,11), in particular perpendicular to the bottom region (7th ). LED luminaire reflector according to claim 2, characterized in that a respective upper region (8d) of each side wall (8a, 8b) is folded outwards, in particular in a plane parallel to the bottom region (7). LED luminaire reflector according to claim 3, characterized in that the outwardly folded portion (8d) of each side wall (8a, 8b) has a width perpendicular to the direction of elongation, which is 15 to 40%, preferably 20 to 30% of the height of the folded portion (8). 8d) above the floor area (7). LED luminaire reflector according to claim 2, characterized in that the side walls (8a, 8b) at least partially, preferably over the entire length and over the entire height of each side wall (8a, 8b) via the bottom portion (7), have an outer shape, which is adapted to the inner shape of a channel-shaped receiving profile (1) of a luminaire, in which the LED reflector (6) is positively inserted due to the adaptation. LED luminaire reflector according to claim 1, characterized in that both side walls (8a, 8b) are asymmetrical to each other, in particular asymmetrically with respect to a central plane (E) parallel to the longitudinal direction and center to the recesses (10, 11), in particular perpendicular to the bottom region (7th ). LED luminaire reflector according to claim 6, characterized in that the asymmetry results from at least one of the following features: a. one of the side walls has a smaller distance to the center plane perpendicular to the longitudinal direction than the other. b. one of the sidewalls has a different angle relative to the floor area than the other c. one of the side walls has a different curvature than the other d. only one of the two side walls (8a) has an upper portion (8d) which is folded outwardly about a folding line lying in the longitudinal direction. LED luminaire reflector according to one of the preceding claims, characterized in that in the longitudinal direction in the bottom region (7) existing recesses (10,11) alternately have different shape, in particular recesses (10,11) with a circular and rectangular cross-section alternately follow each other. LED lights reflector according to one of the preceding claims, characterized in that in the longitudinal direction in the bottom area (7) existing recesses (10) each have a below the bottom portion (7) lying, a respective recess center axis (A) surrounding wall (13), in particular issued from the plane of the bottom portion (7) down. LED luminaire reflector according to claim 9, characterized in that a respective below the bottom portion (7) lying, a respective recess center axis (A) surrounding wall (13) about the Ausnehmungsmittenachse (A) is rotationally symmetrical, in particular in this case dome-shaped. Luminaire having a receiving profile (1) for light sources (2), in particular for LED strips, with a mounting surface (3) arranged in the interior of the receiving profile, on the illuminating means (2) arranged in a longitudinal direction between mutually opposite wall regions (4a, 4b) and are arranged opposite to an opening formed by the upper edges of the wall regions (4a, 4b), wherein the interior of the receiving profile (1) is widening from the mounting surface (3) in the direction of the opening and the opposite wall regions (4a, 4b) At the end near the opening in each case at least one directed to the interior, in particular over the entire length of the receiving profile (1) extending projection (5), characterized in that it comprises an LED luminaire reflector (6) according to one of the preceding claims inside the Receiving profile (1), which by a clamping operative connection between the projections (5) and the resilient upper edges (8c) of the LED luminaire reflector (6) in the receiving profile (1) is attached. Luminaire according to claim 11, characterized in that the LED luminaire reflector (6) is designed according to claim 8 and the recesses (10) of a first shape, in particular with a rectangular cross-section each associated with a light-emitting diode (2), in particular surrounded and the recesses (11) a second form, contribute in particular with a round cross-section to improve the cooling of electronic components, in particular each associated with another electronic component, in particular in each case a component to be cooled (12) surrounded. Luminaire according to claim 11 or 12, characterized in that the interior of the receiving profile (1) is encapsulated with an at least translucent, preferably transparent sealing compound, in particular up to the upper edge of the receiving profile (1), in particular wherein the LED luminaire reflector (6) in the Potting compound is embedded.

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