EP2977674A1 - Light housing with natural convective cooling - Google Patents

Abstract

The present invention relates to a luminaire arrangement comprising a luminaire housing (12) with a first housing part (30) and a second housing part (20), which are spaced apart by an air gap (40), wherein the air gap (40) substantially in one plane extends, and at least a first asymmetry element (50), which is arranged laterally spaced from the air gap (40) that laterally seen in the direction of the plane, a first distance (41) of the lamp housing (12) to the first asymmetry element (50 ). The luminaire housing (12) is designed such that no element is arranged within a distance corresponding to the first distance (41) on a side of the air gap (40) opposite the first asymmetry element (50). The invention further relates to a luminaire with the luminaire arrangement according to the invention.

Description

The invention relates to a luminaire arrangement and a lamp in which heat generated by heat-generated components is dissipated by natural convection or can be.

Between the elements of a luminaire, for example a housing, which has an LED module, and an underlying housing for receiving the electronics, there is usually an air gap, usually a horizontal air gap. In this air gap, the heat emitted by the LED modules is dissipated to the ambient air. A disadvantage of conventional lights, however, is that due to the horizontal arrangement of the air gap no air exchange takes place in the air gap, since the mutually balancing of the air gap masses and thus the air in the air gap is substantially. This leads to a continuous increase in the temperature within the air gap and thus to a continuous increase in the temperature of the LED module. This leads to adverse effects on the function of the LED module as well as the electronics.

For example, the German Offenlegungsschrift DE 10 2008 031 049 A1 a luminaire which requires a dedicated heat sink to dissipate the resulting heat, as the geometry of the luminaire allows only a suboptimal natural convection.

The invention has for its object to provide a luminaire assembly and a luminaire, which ensure a low heat dissipation with little effort, especially without the use of active fans. The object is achieved by the features of the independent claims. Advantageous developments are the subject of the dependent claims.

A luminaire arrangement according to the invention includes a luminaire housing with a first housing part and a second housing part, which are spaced apart from one another by an air gap. The air gap extends essentially in one plane. In addition, the luminaire arrangement includes a first asymmetry element, which is arranged laterally spaced from the air gap, that seen laterally in the direction of the plane, a first distance of the first housing part results to the first asymmetry element. The luminaire housing is designed such that no element is arranged within a distance corresponding to the first distance on a side of the air gap opposite the first asymmetry element. Due to the asymmetrical arrangement of the asymmetric element - ie the deliberately induced asymmetry with respect to each other and laterally spaced from the air gap "sides" in the horizontal - thus ensuring that at a warming of the air in the air gap during operation of the lamp, a pressure difference on the results in opposite sides of the air gap, which in turn results in an air flow towards the first asymmetry element. Thus, the natural convection is promoted by despite preferably horizontal air gap can be generated by increasing the temperature, ie by thermal influences, induced airflow by buoyancy.

Preferably, the first asymmetry element is arranged such that, viewed laterally in the direction of the plane, the first distance results as the distance of the first housing part to the first asymmetry element and a second distance of the second housing part to the first asymmetry element. The luminaire housing is designed in such a way that no element is arranged within the second distance from the second housing part on a side of the air gap opposite the first asymmetry element. It is thus ensured that the asymmetry element is arranged at a suitable distance both with respect to the first housing part and with respect to the second housing part in order to promote natural convection.

Preferably, the second distance is greater than the first distance. The first asymmetry element may be arranged substantially orthogonal to the plane. These measures further promote natural convection.

Preferably, the luminaire arrangement has a second asymmetry element, which is arranged on a side opposite the first asymmetry element laterally spaced from the air gap, that seen laterally in the direction of the plane, a third distance of the lamp housing results to the second asymmetry element. The third distance is greater than the first distance. If the second distance is present, the third distance is greater than the second distance. This ensures that ambient air flows through the third distance into the air gap, where it is heated and emerges on the side of the first distance from the air gap.

Preferably, the second asymmetry element is arranged such that, viewed laterally in the direction of the plane, the third distance of the first housing part to the second asymmetry element and a fourth distance of the second housing part to the second asymmetry element result. These measures further promote natural convection.

Preferably, the fourth distance is greater than the third distance. The second asymmetry element may be arranged substantially orthogonal to the plane. This ensures that ambient air flows into the air gap on the side of the second asymmetry element through the second or fourth distance and leaves the air gap on the side of the first distance or third distance from the air gap after it has been heated in the air gap. This additionally promotes natural convection.

A luminaire arrangement according to the invention can furthermore have a luminaire overall housing in which the luminaire housing with the first housing part and the second housing part as well as the asymmetrical elements are arranged. Thus, the luminaire assembly can be made particularly efficient. Likewise, an asymmetric element can be provided without interfering with the overall appearance of the luminaire.

Preferably, the first asymmetry element and the second asymmetry element are provided as separate elements or integral with at least one of the parts of the luminaire housing and / or, if the luminaire arrangement has a total luminaire housing, formed integrally with the overall luminaire housing. Even by these measures, a particularly efficient production of the luminaire arrangement can be achieved.

A luminaire according to the invention includes a previously described luminaire arrangement. In at least the first housing part heat-generating components are arranged during operation of the lamp. At the heat-generating Components are preferably bulbs, such as LEDs. Thus, in the luminaire according to the invention, heat emitted by the heat-generating components can easily be removed by the good natural convection through the luminaire according to the invention.

In this case, the first asymmetrical element is preferably arranged such that, during operation of the luminaire, an air flow through the air gap in the direction of the first asymmetric element is established by convection of hot air generated by the heat-generating components. Thus, a particularly good cooling of the heat-generating components is achieved.

The luminaire arrangement preferably has a second asymmetry element. The second asymmetry element is arranged such that, during operation of the lamp by convection of hot air generated by the heat generating components, an air flow through the air gap from the direction of the second asymmetry element in the direction of the first asymmetry element sets. This achieves a particularly good natural convection.

Preferably located in the second housing part electronic components for the operation of the lamp, in particular a driver circuit. Thus, heat generated by the driver circuit can be dissipated favorably.

Fig. 1

ein herkömmliches Leuchtgehäuse;

Fig. 2

ein erstes Ausführungsbeispiel der erfindungsgemäßen Leuchte beinhaltend ein erstes Ausführungsbeispiel der erfindungsgemäßen Leuchtenanordnung, und

Fig. 3

ein zweites Ausführungsbeispiel der erfindungsgemäßen Leuchte beinhaltend ein zweites Ausführungsbeispiel der erfindungsgemäßen Leuchtenanordnung.

The invention will be described by way of example with reference to the drawing, in which an advantageous embodiment of the invention is shown. In the drawing show:

Fig. 1

a conventional light housing;

Fig. 2

a first embodiment of the lamp according to the invention including a first embodiment of the lamp assembly according to the invention, and

Fig. 3

A second embodiment of the luminaire according to the invention comprising a second embodiment of the luminaire arrangement according to the invention.

First, based on the Fig. 1 the general structure and the general operation of a conventional lamp and a conventional lamp housing explained. Based on Fig. 1 In addition, the underlying problem is shown in more detail. Subsequently, based on Fig. 2 and Fig. 3 on the structure and operation of several embodiments of the lamp according to the invention or the light assembly according to the invention received. Identical elements have in some cases not been shown and described in similar illustrations.

In Fig. 1 an exemplary lamp 1 is shown. In the view shown here, a cross section through an elongate lamp is shown. In this case, the luminaire 1 comprises a luminaire housing 8, which comprises a first housing part 4 and a second housing part 2. The second housing part 2 is arranged above the first housing part 4 and separated by an air gap 7 thereof.

The second housing part 2 includes a driver circuit 3 for operating the lamp 1, in particular for operating an LED module 5, which is arranged in the first housing part 4. The first housing part 4 also includes a viewing window 6, which is only covered transparent and thus allows light emission of the LED module downwards.

During operation of the luminaire 1, the LED module 5 primarily heats up and, to a lesser extent, the driver circuit 3. This results in a heating of the air in the air gap 7. Since on both sides - ie left and right in Fig. 1 - The air gap 7 is an identical pressure, the air masses are equalized. There is no appreciable natural convection through the air gap 7 therethrough. It thus accumulates the hot air generated by the heated LED module 5 by the driver circuit 3 in the air gap 7. This leads to a heating of the lamp housing 8 and thus to a heating of the LED module 5 and the driver circuit. 3

In Fig. 2 is a first embodiment of the lamp 11 according to the invention including a light housing 12, also shown in a sectional view. The luminaire housing 12 includes a first housing part 30 and a second housing part 20. The second housing part 20 is arranged above the first housing part 30. The second housing part 20 includes a driver circuit 21. In this case, the first housing part 30 contains an LED module 31 and a transparent cover 32, which allows light to exit downwards. The first housing part 30 is separated from the second housing part 20 by an air gap 40.

In addition, the luminaire housing 12 includes a first asymmetry element 50, which is arranged laterally next to the first housing part 30 and the second housing part 20. The asymmetric element 50 is arranged orthogonal to a plane described by the air gap 40. In this case, the asymmetrical element 50 has a first distance 41 from the first housing part 30. Furthermore, it has a second distance 42 to the second housing part 20. The luminaire housing 12 and the asymmetric element 50 form the luminaire arrangement according to the invention.

It can be clearly seen here that no element is arranged on the side of the air gap 40 opposite the asymmetry element 50. In particular, no element is arranged within a distance corresponding to the first distance 41, and particularly advantageously within a distance corresponding to the second distance 42. This results in an asymmetry of the pressure conditions on the two sides of the lamp housing 12; low pressure on sides of the asymmetric element 50 and high pressure on the opposite side of the air gap 7 to the asymmetric element 50, so that air is "sucked" from the high-pressure side to the low-pressure side. That is, there is an air flow from the air gap 40 toward the asymmetry element 50 and in the direction of the second housing part 20, away from the first housing part 30. Since no corresponding element is arranged on the side of the air gap 40 opposite the asymmetry element 50, non-flowing warmed by ambient air to replace the leaked air as described above in the air gap 40. This results in a strengthened natural convection through the air gap 40 therethrough. The air flow is illustrated by arrows. This flow ensures a significantly increased heat removal compared to the Fig. 1 illustrated luminaire housing. 8

In Fig. 3 is a second embodiment of the lamp 11 according to the invention including a lamp housing 12, shown. Here, the luminaire housing 12 additionally includes a second asymmetry element 51, which is arranged on the side of the air gap 40 opposite the first asymmetry element 50. The second asymmetry element 51 is arranged at a third distance 43 to the first housing part 30 and at a fourth distance 44 to the second housing part 20. The third distance 44 is preferably greater than the first distance 41. The fourth distance 44 is preferably greater than the second distance 42. Preferably, the third distance 43 is greater than the second distance 42. The light housing 12 and the asymmetry elements 50, 51 thereby form the light assembly according to the invention.

It is thus ensured that the opening or the distance between the second asymmetry element 51 and the luminaire housing 12 (or here the first housing part 30) is significantly larger than the opening or the distance between the first asymmetry element 50 and the luminaire housing 12 (FIG. or here the first housing part 30). Due to the asymmetry of the pressure conditions on the two sides of the lamp housing 12, as described with respect to the first embodiment described, an air flow through the opening between the second asymmetry member 51 and the lamp housing 12 (eg. Here the first housing part 30) into the air gap 40 causes. The warming / heated air there exits on the side of the first asymmetric element 50 and flows in the direction of the second housing part 20 or upwards; So in the sense of a natural convection. The air flow is indicated by arrows in Fig. 2 clarified.

The second distance 42 is preferably still greater than the first distance 41. The third distance 43 is preferably smaller than the fourth distance 44th D.h. the first housing part 30 preferably has a greater width than the second housing part 20. This additionally promotes natural convection.

The effect described can be equated with the effect of airfoils, which leads to a corresponding negative pressure and thus a suction effect in a predetermined direction due to a different path or an asymmetry in the support surface.

In the previously illustrated embodiments, the asymmetry is created by additional asymmetry elements 50, 51. The asymmetrical elements 50, 51 can also be used as part of the luminaire housing 12-that is to say one of the housing parts 20, 30-or of the luminaire overall housing accommodating the housing parts 20, 30 (not shown) and be provided as separate elements or integrally. It is likewise conceivable for the asymmetry to be brought about by elements of the luminous arrangement 12 arranged asymmetrically (for example laterally offset from each other). Particularly advantageous are asymmetrical configurations that do not affect the external appearance of the lamp. The asymmetrical elements 50, 51 are therefore not limited in their design and thus do not have to be present as plate-like elements, as shown in the figures.

The luminaire can be present, for example, as suspended or surface-mounted luminaire. It is also conceivable that the luminaire is present as a recessed luminaire, with asymmetrical elements being laminated by a recessed ceiling receiving the recessed luminaire. Thus, for example, the transparent cover 32 or the light exit opening having side of the lamp or lamp assembly are aligned with a false ceiling.

A non-orthogonal arrangement of the asymmetric elements 50, 51 with respect to the air gap 40 is also conceivable, provided that the natural convection is maintained.

The invention is not limited to the illustrated embodiment. As already mentioned, different heat-generating components can be arranged within the housing parts and be cooled by the described luminaire housing. All features described above or features shown in the figures can be combined with each other in any advantageous manner within the scope of the invention. Also, the design of a luminaire arrangement or luminaire according to the invention is not limited by the invention as long as there is a corresponding air gap and the side of the same present asymmetry to produce a natural convection.

Claims (14)

Luminaire arrangement comprising: a luminaire housing (12) having a first housing part (30) and a second housing part (20), which are spaced apart from one another by an air gap (40), wherein the air gap (40) extends substantially in a plane, and at least one first asymmetry element (50) which is arranged at a distance from the air gap (40) such that a first distance (41) of the luminaire housing (12) to the first asymmetry element (50) results laterally in the direction of the plane, wherein the luminaire housing (12) is designed such that no element is arranged within a distance corresponding to the first distance (41) on a side of the air gap (40) opposite the first asymmetry element (50). Luminaire arrangement according to claim 1,
wherein the first asymmetry element (50) is arranged such that, viewed laterally in the direction of the plane, the first distance (41) as the distance between the first housing part (30) to the first asymmetry element and a second distance (42) of the second housing part (20 ) to the first asymmetric element (50), and wherein the luminaire housing (12) is formed such that on a side of the air gap (40) opposite the first asymmetry element (50) no element within the second distance (42) from the second housing part (30) is arranged. Luminaire arrangement according to claim 2,
wherein the second distance (42) is greater than the first distance (41). Luminaire arrangement according to one of claims 1 to 3,
wherein the first asymmetry element (50) extends substantially orthogonal to the plane. Luminaire arrangement according to one of claims 1 to 4, comprising: a second asymmetry element (51), which is arranged on a side opposite the first asymmetry element (50) opposite side of the air gap (40), that seen laterally in the direction of the plane, a third distance (43) of the lamp housing (12) to the second asymmetric element (51), wherein the third distance (43) is greater than the first distance (41) and, when the second distance (42) is present, the third distance (43) is greater than the second distance (42). Luminaire arrangement according to claim 5,
wherein the second asymmetry element (51) is arranged such that viewed laterally in the direction of the plane, the third distance (41) as the distance of the first housing part (30) to the second asymmetry element (51) and a fourth distance (44) of the second Housing part (20) to the second asymmetry element (51) results. Luminaire arrangement according to claim 6,
wherein the fourth distance (44) is greater than the third distance (43). Luminaire arrangement according to one of claims 5 to 7,
wherein the second asymmetric element (51) extends substantially orthogonal to the plane. Luminaire arrangement according to one of claims 1 to 8, further comprising a luminaire total housing,
wherein the luminaire housing (12) with the first housing part (30) and the second housing part (20) and the asymmetry elements (50, 51) are provided in the luminaire overall housing. Luminaire arrangement according to one of claims 1 to 9,
wherein the first asymmetry element and the second asymmetry element are provided as separate elements or formed integrally with at least one of the parts (20, 30) of the luminaire housing (12) and / or, if the luminaire arrangement has a total luminaire housing, integrally with the luminaire overall housing. Luminaire (11) comprising a luminaire arrangement according to one of claims 1 to 10,
wherein at least in the first housing part (30) during operation of the lamp (11) heat-generating components (21), in particular bulbs such as LEDs, are provided. Luminaire (11) according to claim 11,
wherein the first asymmetric element (50) is arranged such that during operation of the luminaire (11) by convection of warm air generated by the heat-generating components (31) an air flow through the air gap (40) in the direction of the first asymmetry element (50 ). Luminaire (11) according to claim 11 or 12, comprising a luminaire arrangement according to one of claims 5 to 10,
wherein the second asymmetric element (51) is arranged such that during operation of the luminaire (11) by convection of warm air generated by the heat-generating components (31) an air flow through the air gap (40) from the direction of the second asymmetry element (51 ) in the direction of the first asymmetry element (50). Luminaire (11) according to one of claims 11 to 13, wherein in the second housing part (20) electronic components (21) for operating the lamp, in particular a driver circuit, are provided.

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