DE202012103495U1 - Carrier element in a lighting device and lighting device with such a support element - Google Patents

Abstract

Carrier element (10) in a lighting device (18), wherein the carrier element (10) in cross section has a regular polygonal contour with a plurality of partial surfaces (12) and wherein the carrier element (10) is hollow in the interior, characterized in that starting of each partial surface (12) extend inside the carrier element (10) cooling ribs (14) and that the carrier element (10) in the region of a transition between two adjacent partial surfaces (12) outwardly projecting and in the longitudinal direction of the carrier element (10) extending webs ( 22).

Description

The invention relates to a carrier element in a lighting device and, moreover, to a lighting device, especially a lighting device in the form of an outdoor light, with such a carrier element.

Carrier elements of the type mentioned for lighting devices, especially outdoor lights, are known. The Applicant uses, for example, a carrier element in the manner of a Vierkanterrohrs of an aluminum profile and attaches to such a support member on one or more of the outwardly facing surfaces of the surface portions of the support member LED modules, so that the support member can be installed in total in a lighting device.

An object of the present invention, starting from this prior art is to provide a further embodiment of a support member of the type mentioned, which is characterized by additional advantages. Another object of the present invention is - also starting from the outlined above prior art - is to provide a lighting device that can be produced quickly and easily and in consistent quality.

This object is achieved with a carrier element with the features of claim 1. For this purpose, in the case of a carrier element in or for a lighting device, wherein the carrier element has a polygonal contour, in particular a regular polygonal contour, with a plurality of partial surfaces, the carrier element being hollow inside, provided that starting from each partial surface extend into the interior of the support member cooling fins and that the support member has in the region of a transition between two adjacent faces outwardly projecting and extending in the longitudinal direction of the support member webs.

The advantage of the embodiment of the carrier element according to the invention consists firstly in that a better heat dissipation is possible by the inwardly facing cooling fins and secondly that the webs when attaching LED modules or the like on the support member for fixing and / or adjustment of such LED Modules are effective.

Especially with regard to the aspect of the adjustment of such LED modules is to be noted that could be in the above-mentioned known carrier element only with some effort an orientation of an LED module parallel to the longitudinal extent of the support member produced. If the LED module was glued to the subarea of the known carrier element, a manual adjustment was required and the LED module had to be held at least until the desired adhesive effect sets, so with a commonly used hot melt adhesive until it cools down. When the respective LED module was detachably attached to the partial surface of the known support member by means of screws or the like, the LED module on the relevant partial surface had to be manually displaced until screw holes in the LED module were aligned with threaded holes in the support member and held in this position until the or each screw connection was made. All this makes the loading of the known support member comparatively expensive because the required adjustment is time consuming. This has led to cost disadvantages in the use of the previous support element.

Specifically, the lateral and extending in the longitudinal direction of the support member webs allow easy and anytime exact adjustment of a respective to be mounted on the support element LED module. The particular LED module to be mounted can be applied to at least one of the webs, whereby an exactly parallel to the longitudinal direction of the carrier element alignment of the respective LED module is ensured. If the LED module is combined with the carrier element by gluing, the adhesive-provided LED module can be pushed with one of its outer edges to one of the webs and in this position, the effectiveness of the adhesive bond can be awaited. When the LED module is connected to the support member by screws or the like, the LED module can be applied with one of its outer edges to one of the webs and by moving the LED module in the longitudinal direction of the support member in a simple manner an aligned match of Holes in the LED module and tapped holes in the support element are visited. The latter is based on the fact that with a known position of the holes in the LED module and a so well known distance of such holes from one edge of the LED module, the threaded holes in the support element at a corresponding distance from the respective part surface as the mounting location of the LED module laterally limiting web can be attached.

Advantageous embodiments of the invention are the subject of the dependent claims. This used backlinks point to the further development of the subject matter of the main claim by the features of the respective subclaim; they are not as a waiver of the achievement of an independent, objective protection for the feature combinations of the to understand the dependent claims. Furthermore, with a view to an interpretation of the claims in a closer specification of a feature in a subordinate claim, it is to be assumed that such a restriction does not exist in the respective preceding claims.

Since the subject-matter of the subclaims can form separate and independent inventions with regard to the prior art on the priority date, the Applicant reserves the right to make them the subject of independent claims or statements of division. They may further contain independent inventions having an independent of the subjects of the preceding sub-claims design.

In a particular embodiment, the carrier element has exactly four partial surfaces. The support element is thus rectangular in cross section, in particular square. Such a regular shape allows the attachment of at least one LED module on or at each of the four partial surfaces. The regular contour of the carrier element allows for its use in a lighting device and an occupancy with multiple LED modules a regular light propagation.

In an alternative embodiment, the carrier element has exactly six partial surfaces. The carrier element is therefore honeycomb-shaped in cross-section. In a preferred embodiment of a carrier element with six partial surfaces, a contour in the form of a regular hexagon (regular hexagon) with partial surfaces each having an identical width is provided. Such a regular shape allows the attachment of at least one LED module on or on each of the six partial surfaces. The regular contour of the carrier element allows a particularly regular light propagation when used in a lighting device, wherein compared to a support element with four faces the regularity of light propagation is increased and when using such lighting devices subjectively in the circumferential direction of an imaginary circle with the lighting device in the center none Brightness differences are perceptible.

If a measured over a width of a partial surface distance between two each of these partial surface laterally limiting webs is tuned to a width of a combinable with the support element LED module, the LED module can be adjusted on the part surface by both lateral webs simultaneously as a stop for the long edges of each LED module act. The LED module can thus be pushed as it were on the respective sub-area and the two webs act on the one hand as a lateral boundary and on the other hand cause at any time parallel alignment with the longitudinal extent of the support element. When fixing an LED module so positioned on the carrier element, either by gluing or screwing, the LED module may need to be displaced in the direction of the longitudinal extension of the carrier element for exact positioning of the LED module. The webs act when moving the LED module as rails and both fixing by gluing as well as fixing by screws can be easily and easily find the desired position and fix.

If each partial surface between each two webs adjoining the partial surface laterally comprises a flat surface on which or on which at least one LED module can be attached, the displacement described above is particularly easy to accomplish. In addition, a particularly good heat transfer from the respective LED module to the partial surface of the carrier element and thus the carrier element as a whole ensured by the flat surface. The heat thus absorbed by the carrier element can be released into the ambient air by the cooling fins encompassed by the carrier element and pointing into the interior of the carrier element, thus avoiding overheating of the LED modules and possibly impairing the function or reducing the service life of the LED modules.

The further object mentioned above is achieved with a lighting device having the features of the further independent claim. For this purpose, it is provided in the case of a lighting device that it comprises a carrier element as described here and below, and that LED modules can be attached or attached to individual partial surfaces of the carrier element.

The advantage of this aspect of the invention is that a precisely parallel alignment with the longitudinal extent of the carrier element and between adjacent LED modules a constant distance is ensured by the use of the support element proposed here and possible embodiments for each combined with the support element LED module. This results for individual lighting devices through the use of the support element exact positioning of the individual LED modules and for several lighting devices uniformity and homogeneity, which makes itself noticeable during later operation with lighting devices in spatial proximity to each other by a uniform light propagation.

The use of a carrier element as described here and below for a Lighting device or multiple lighting devices also has the advantage that when configuring the support element, so when combining single or multiple LED modules with the support element, the later resulting in the use of lighting device light propagation can be determined. Thus, for example, individual partial surfaces adjoining one another on the carrier module can each be provided with an LED module, while other adjacent partial surfaces remain free. This leads to a directed light propagation. Such directed light propagation is useful, for example, if the surface of a sidewalk is to be illuminated and, in a manner known per se, illumination devices are arranged on the edge of the sidewalk and at normally regular intervals from one another. In such a situation, one will occupy facing in the direction of the sidewalk partial surfaces of the support member with LED modules, while the remaining part surfaces of the support element remain free. Of course, a configuration of the carrier element that is suitable in this respect can also take place before it is combined with the illumination device such that individual subareas are occupied by LED modules and other subareas remain free and when the carrier element is combined with the illumination device it is oriented, ie rotated the desired direction of light propagation results. Another possibility for configuring the carrier element is that alternately individual subareas are occupied by LED modules and other sub-areas remain free, so that can be set in this way the deliverable by the illumination device during operation amount of light. In this regard, a wide variety of configurations are conceivable, for example, such that in each case one sub-area is occupied by an LED module, the adjacent sub-area remains free and the partial area adjacent to the remaining sub-area is again occupied and so on. For a higher amount of light is considered to occupy two adjacent sub-areas with an LED module, then release a sub-area and then occupy again two adjacent sub-areas with an LED module. For a smaller amount of light, two adjacent partial areas remain free and the partial area adjoining the free partial areas is occupied by an LED module and so on. Arrangements in this type are summarized under the keyword of a regular distribution of the LED modules on the faces of the support element. In addition come as in this way regularly distributed LED modules and LED modules with a different number of bulbs into consideration, in order to be able to influence in this way additional influence on the amount of light emitted, optionally on the amount of light emitted in different directions of propagation.

When attaching the carrier element in a lighting device, a particular embodiment is that the provided with at least one LED module support element is oriented vertically in the illumination device. In such a vertical orientation of the support member extends the longest axis of the support member parallel to the usually also vertical orientation of the illumination device, which often includes a mast, a pedestal or the like and in which above such a base is the housing of the illumination device, for example a Glass cylinder or made of a transparent or translucent plastic cylinder or the like, in the interior of which the respective light source, in this case the carrier element with the at least one LED module, is located. With such a vertical orientation of the carrier element, it is ensured that an upwardly directed air flow, which is effective for heat dissipation of the carrier element, can be established in the interior of the carrier element.

In a particular embodiment of the illumination device, it is provided that a fan, in particular a fan combined with the carrier element, is located in the illumination device below the carrier element. Such a fan is effective to improve and accelerate the heat transfer from the support member, especially its cooling fins, to the ambient air. The fan can be permanently in operation or activated by temperature control. The fan complements the already achieved by the cooling fins heat dissipation of the LED modules in a favorable manner.

In a further particular embodiment of the illumination device, it is provided that the support element is associated with a foot part, in particular a foot part in the form of a profile corresponding to the profile of the support element, and that the support element is mounted at a distance from the foot part on the foot part. In this way, arises between the foot and the carrier element acting as an air inlet gap. There incoming air rises in the support member and passes through the cooling fins, so that there is a heat transfer to the passing air. The heated rising air also leads to a chimney effect, so that constantly flows over the distance between the foot and the support element ambient air and in this way results in an effective cooling (cooling) of the support element. The amount of air in this way adjusting air flow can still be favorably influenced by - as already described - the carrier element is associated with a fan. The fan may be on an upper side of the foot part, on an underside of the carrier element or an upper side of the carrier element.

An embodiment of the invention will be explained in more detail with reference to the drawing. Corresponding objects or elements are provided in all figures with the same reference numerals.

The or each embodiment is not to be understood as limiting the invention. Rather, in the context of the present disclosure, modifications and modifications are possible, in particular those variants and combinations, for example, by combination or modification of individual in conjunction with the described in the general or specific description part and in the claims and / or the drawing features or Elements or method steps for a person skilled in the art with regard to the solution of the task can be removed and lead by combinable features to a new object.

Show it

1 a representation of a cross section of an embodiment of a carrier element according to the invention,

2 the carrier element according to 1 in a plan view of the cross section and in a side view,

3 a representation of a cross section of a further embodiment of a carrier element according to the invention,

4 the carrier element according to 3 in a plan view of the cross section and in a side view,

5 a schematically simplified representation of an LED module as attachable to the support element bulbs,

6 an also schematically simplified representation of a support member in a plan view and a side view with attached LED modules and

7 a schematically simplified representation of, for example, acting as an outdoor light illumination device with a equipped with LED modules support element according to 6 ,

1 shows an embodiment of a carrier element 10 with a hexagonal basic contour and correspondingly six partial surfaces 12 who at the in 1 also all shown the same size, ie on the support element 10 each have an equal width. The hexagonal basic contour is an example of a cross-sectionally regular polygonal contour. The carrier element 10 is hollow inside and starting from each face 12 extend cooling fins 14 inside the support element 10 ,

The length of the cooling fins 14 varies over the width of the respective partial area 12 , Accordingly, those are on the sides of the faces 12 emerging cooling fins 14 short and the length increases to the middle of the respective partial area 12 to move towards the other side of the subarea 12 to lose weight again. This results in inclusion of the respective partial area 12 and the resulting cooling fins 14 a triangular envelope contour, wherein the triangular envelope contour in the illustrated embodiment is an equilateral triangle or at least substantially an equilateral triangle, at least one isosceles triangle. Inside the support element 10 let the cooling fins 14 a channel 16 free, which here has a circular contour, as indicated in the drawing by the local arc. This channel 16 allows, when using the illustrated profile as a support element 10 in a lighting device 18 ( 7 ) in a vertically oriented support element 10 adjusts an airflow at a lower edge of the carrier element 10 begins and the carrier element 10 leaves at its upper edge again. This air flow then also causes the rising air to the cooling fins 14 along sweeps and then results accordingly in a heat dissipation of the support element 10 when it receives heat from the or each bulb in the operation of one or more bulbs.

In the area of a joint between every two faces 12 is in the material of the profile of the support element 10 and at least partially by two cooling fins emerging there 14 a place for a hole 20 or tapped hole formed. Here screws or rods or spacers can be inserted.

On the outer surface of the support element 10 are in the range of a transition between every two adjacent faces 12 outwardly projecting and in the longitudinal direction of the support element 10 running and as bars 22 formed effective projections. These serve as adjustment aid for with the support element 10 combinable light sources, in particular bulbs in the form of LED modules 24 ( 5 ).

2 shows in the lower part of the support element 10 in its cross-sectional representation as in 1 , Starting from this is in the upper range of 2 the carrier element 10 in vertical Orientation and shown in a side view. The view goes head-on on one of the faces 12 , which is thus oriented in the illustrated situation perpendicular to the viewing direction. Right and left adjacent to this part 12 are two more faces 12 , which appear shortened due to their inclination towards the viewing direction. Visible in the further are the three visible partial surfaces 12 limiting ridges 22 namely the two bridges 22 , which is the perpendicular to the direction oriented partial surface 12 limit as well as the other bars 22 at the end of the aforementioned bridges 22 subsequent partial surfaces 12 ,

Each subarea 12 is at least piecewise flat, so that each face 12 between each two laterally to the partial surface 12 adjacent jetties 22 comprises at least one flat surface on which or on the appropriate lighting means are attachable, as will be described below with reference to the later figures. In the illustrated embodiments, situations are shown in which the partial surfaces 12 and thus the entire area between two adjacent bars 22 overall are or is. As 2 indicated in the lower area, can be in each sub-area 12 a threaded hole 26 or a plurality of tapped holes for mounting an LED module 24 be introduced.

3 shows an alternative embodiment of the carrier element 10 with a regular polygonal contour. In contrast to the hexagonal polygonal contour according to 1 here is a carrier element 10 with a quadrangular contour and correspondingly four partial surfaces 12 shown. Apart from the smaller number of faces 12 corresponds to the carrier element 10 according to 3 in its essential characteristics the carrier element 10 in 1 , So is the carrier element 10 according to 3 hollow inside. Here, too, extend from each partial area 12 cooling fins 14 inside the support element 10 and also here the carrier element 10 in the area of a transition between two adjacent subareas 12 each outwardly projecting and in the longitudinal direction of the support element 10 running bridges 22 on.

4 shows in analogy to the illustration in 2 in the lower area, first the support element 10 in the cross-sectional view and then in the upper region of the carrier element 10 in vertical orientation and in a side view. At exactly four each arranged at right angles to each other faces 12 (see 3 ) goes accordingly in the 4 shown side view of the view only on a partial surface 12 and this is oriented at right angles to the line of sight. Laterally adjacent to this visible partial surface 12 the two are the partial surface 12 limiting ridges 22 to recognize. The side of the visible part surface 12 adjacent subareas 12 are at the in 4 selected viewing direction not visible.

5 shows in schematically simplified form an LED module 24 as an example of a support element described so far 10 or other support elements with the same features standing in the foreground bulbs. The LED module 24 is on a circuit board 28 or PCB and here includes four LED units 30 , Instead of four LED units 30 are also LED modules 24 with more or less LED units 30 conceivable and usable, for example LED modules 24 with three LED units 30 , LED modules 24 with six LED units 30 , LED modules 24 with nine LED units 30 and so on.

As the front of the LED module 24 In the following, that side is understood to be that of the operation of the LED module 24 , ie when activating one or more LED units 30 , the light propagation takes place. On its back side, each LED module points 24 in a non-illustrated form a metallic coating, which is used to dissipate heat from each LED unit 30 and for heat transfer to a support on which the LED module 24 is attached serves. As a carrier comes specifically a carrier element 10 of the type described here into consideration and the heat transfer takes place accordingly to the respective partial surface 12 the carrier element 10 that with such a LED module 24 is occupied. The carrier element 10 is made of aluminum or a similar non-conductive for electrical current, but good heat conducting material, so that the carrier element 10 for the or each attached LED module 24 how a large heatsink acts and the heat-emitting surface of an LED module 24 or more LED modules 24 increased.

In 5 are for one embodiment by screwing to a support member 10 combinable LED module 24 drilling 32 in the board 28 of the LED module 24 represented by the screw in a manner known per se can be inserted, for mounting the LED module 24 on the carrier element 10 in intended and in the support element 10 formed threaded holes 26 ( 2 ) intervene.

In 6 is the example of a carrier element 10 with hexagonal basic contour (cf. 1 ) An assignment of its partial areas 12 with LED modules 24 shown. It can be seen that the width of the LED modules 24 and the distances between each two adjacent bars 22 are coordinated. As a result, the webs 22 as an adjustment aid for an exactly parallel alignment of the LED modules 24 to the longitudinal extent of the support element 10 usable. In the illustrated embodiment, where the width of an LED module 24 exactly or at least essentially the width of one between each two webs 22 formed part surface 12 corresponds, the two are the respective partial area 12 laterally bounding webs 22 effective as an adjustment aid. For LED modules 24 with a smaller width, at least one of the respective partial area 12 limiting ridges 22 used as adjustment aid. In the illustrated embodiment with the exact width of the LED modules 24 coordinated width of the faces 12 and thus a corresponding distance between each two adjacent webs 22 the two act the respective partial surface 12 limiting ridges 22 when attaching an LED module 24 like rails and the bars 22 allow only a translational movement of the LED module 24 on the carrier element 10 in exactly one direction, namely in the direction of the longitudinal extent of the carrier element 10 , This displaceability can be used to drill holes 32 in the LED module 24 with threaded holes 26 in the carrier element 10 to bring the LED module 24 by screwing with the carrier element 10 can be combined. The same applies mutatis mutandis, if the LED modules 24 by gluing with the carrier element 10 be combined and ensured by moving all the LED modules 24 at a same height on the support element 10 are located.

If at the top it was taken care that the width of the faces 12 and the distance between each two adjacent bars 22 on the width of the LED modules 24 is tuned, this can of course apply the other way around and for a given carrier element 10 with a correspondingly given width of the local subareas 12 and a correspondingly given distance between each two adjacent webs 22 can also change the width of the LED modules 24 be tuned to these dimensions.

7 finally shows a lighting device 18 with a carrier element 10 of the type described here. As can be seen in the figure at individual partial surfaces 12 the carrier element 10 , namely on all visible partial surfaces 12 the carrier element 10 , LED modules 24 appropriate. Other mounting situations of the LED modules 24 are also conceivable, especially the LED modules 24 regularly on the faces 12 of the carrier element 10 be distributed, with the mounting situation shown a regular distribution of the LED modules 24 represents, if exactly three sub-areas 12 are occupied and the other, not visible partial surfaces 12 are not occupied or if in addition to the three visible faces 12 also the three invisible faces 12 each with LED modules 24 are occupied.

7 also shows that with at least one LED module 24 provided carrier element 10 in the lighting device 18 is vertically oriented. The carrier element 10 can be particularly good as a heat sink for the or each mounted LED module 24 because an internal air flow will then be inside the lighting device 18 rises to the top, so that there is a good cooling effect. For such an air flow is basically necessary that a bottom of the support element 10 a possibility for influx of ambient air is given. This can be achieved by an appropriate attachment of the support element 10 to reach. At the in 7 illustrated embodiment is provided that the carrier element 10 a foot part 34 is assigned, namely, for example, a footboard 34 in the form of the profile of the support element 10 corresponding profile. The acting as inflow opening for the ambient air distance between the foot part 34 and carrier element 10 can then be achieved particularly easily by the fact that in the profile of the support element 10 formed and in the longitudinal direction of the support element 10 running holes 20 ( 1 . 3 ) Spacers, for example, threaded rods or the like are introduced. The between foot part 34 and carrier element 10 remaining distance is also suitable as a mounting location for a fan (not shown), so that when operating the fan, the amount of in the support element 10 incoming ambient air can be increased in order to achieve an even better cooling effect (heat dissipation). The fan can then be in the area of an upper edge of the foot part 34 or a lower edge of the carrier element 10 to be appropriate. Depending on the height of the fan compared to a situation without a fan, the distance between the foot part 34 and carrier element 10 increase. A basically same effect can be achieved if the fan in the region of an upper edge of the support element 10 is attached. The fan may operate permanently or be automatically activated based on a reading obtained from a temperature sensor.

Individual prominent aspects of the description submitted here can thus be briefly summarized as follows: It becomes a carrier element 10 in a lighting device 18 or for a lighting device 18 indicated, wherein the carrier element 10 in cross-section a regular polygonal contour with a plurality of faces 12 and wherein the carrier element 10 is hollow inside and is characterized by the fact that starting from each partial surface 12 inside the support element 10 cooling fins 14 extend and that the support element 10 in the area of a transition between two adjacent subareas 12 outwardly projecting and in the longitudinal direction of the support element 10 running bridges 22 and a lighting device 18 with such a carrier element 10 ,

LIST OF REFERENCE NUMBERS

10

support element

12

subarea

14

cooling fin

16

channel

18

lighting device

20

Bore (in the carrier element)

22

web

24

LED module

26

Threaded hole (in the carrier element)

28

Board (of the LED module)

30

LED unit

32

Hole (in the LED module)

34

footboard

Claims (10)

Carrier element ( 10 ) in a lighting device ( 18 ), wherein the carrier element ( 10 ) in cross-section a regular polygonal contour with a plurality of partial surfaces ( 12 ) and wherein the carrier element ( 10 ) is hollow inside, characterized in that starting from each partial surface ( 12 ) into the interior of the carrier element ( 10 ) Cooling fins ( 14 ) and that the carrier element ( 10 ) in the region of a transition between two adjacent faces ( 12 ) projecting outwards and in the longitudinal direction of the carrier element ( 10 ) running webs ( 22 ) having. Carrier element ( 10 ) according to claim 1 with exactly four partial surfaces ( 12 ). Carrier element ( 10 ) according to claim 1 with exactly six partial surfaces ( 12 ). Carrier element ( 10 ) according to any one of the preceding claims, wherein an across the width of a partial area ( 12 ) measured distance between each two webs ( 22 ) to a width of one with the support element ( 10 ) combinable LED module ( 24 ) is tuned. Carrier element ( 10 ) according to claim 4, wherein each partial area ( 12 ) between each two laterally on the partial surface ( 12 ) adjacent webs ( 22 ) comprises a flat surface on or on the at least one LED module ( 24 ) is attachable. Lighting device ( 18 ) with a carrier element ( 10 ) according to one of the preceding claims, wherein at individual partial surfaces ( 12 ) of the carrier element ( 10 ) LED modules ( 24 ) are mounted. Lighting device ( 18 ) according to claim 6, wherein the LED modules ( 24 ) regularly on the partial surfaces ( 12 ) of the carrier element ( 10 ) are distributed. Lighting device ( 18 ) according to claim 6 or 7, wherein the at least one LED module ( 24 ) provided carrier element ( 10 ) in the illumination device ( 18 ) is vertically oriented. Lighting device ( 18 ) according to claim 8, wherein in the illumination device ( 18 ) below the carrier element ( 10 ) a fan, in particular a with the support element ( 10 ) combined fan is located. Lighting device ( 18 ) according to claim 8 or 9, wherein the carrier element ( 10 ) a foot part ( 34 ), in particular a foot part ( 34 ) in the form of a profile of the support element ( 10 ) corresponding profile, and wherein the carrier element ( 10 ) at a distance from the foot part ( 34 ) on the foot part ( 34 ) is attached.

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