DE202010004868U1 - LED bulbs - Google Patents

Abstract

LED lighting means (40) having a tube-like cooling element (10) on which a plurality of printed circuit boards (15) equipped with LEDs (16) are arranged on the outside, wherein the cooling element (19) essentially in vertical alignment in a lamp housing (45, 55 ) is arranged
characterized,
the cooling element (10) forms an inner flow channel (19) and
the cooling element (10) is thermally coupled to a heat sink (1) in its upper end region in the installed position, and
the cooling body (1) has a continuous cooling channel (2) aligned with the flow channel (19) of the cooling element (10).

Description

The The invention relates to an LED lamp with a tube-like design Cooling element, on which several equipped with LED Printed circuit boards on the outside are arranged, wherein the cooling element in Essentially arranged in vertical alignment in a luminaire housing is.

In The lighting technology is being used increasingly energy-saving LED. In particular, for the illumination of streets and squares so-called High performance LED used which in multiple arrangement a printed circuit board are placed. In particular, a 360 ° round lighting to be able to reach will be several equipped with LED Printed circuit boards on the outside on a supporting body placed. Since in particular high-power LED high heat development have, is such a support body usually designed tube-like and also serves as a cooling element. For a 360 ° round lighting to be able to reach Such a LED bulb with the tube-like as cooling element serving support body to be arranged substantially in vertical alignment in a luminaire housing.

Around a cooling effect for the Reaching LED is this cooling element with an airflow for cooling to flow through. It is inevitable the cooling effect in the area of the air inlet into the cooling element greater than in the region of the air outlet, since the flow of air through the cooling element heats the air stream. To achieve a sufficient air flow and thus sufficient cooling to be able to For this purpose, usually electrically operated blowers are used, so that one possible optimal cooling effect for the LED is reachable.

at a big one Number in the axial direction of successively arranged LED is the Cooling effect on the air outlet side often not sufficient to be outside in this area on the cooling element optimally cool arranged LED to be able to. Furthermore, the control effort relative to the blower used is relative high, making such LED lights relatively expensive in their manufacture are.

Accordingly, lies The invention is based on the object, an LED bulb with a tube-like cooling element to design such that optimal cooling of all the outside on the cooling element arranged LED allows is omitted and wherein an air flow generating cooling fan can be.

The Task is inventively together solved with the features of the preamble of the claim in that the cooling element an inner flow channel forms and that the cooling element in its installation position in the upper end region with a heat sink thermally is coupled and that the heat sink a continuous to the flow channel of the cooling element aligned cooling channel having.

By the embodiment of the invention will an LED bulb to disposal placed, in which the outside on the cooling element arranged LED are cooled evenly. For this purpose, in a vertical mounting position of the cooling element in the upper End area an additional Heatsink provided, which with the cooling element thermally coupled. This heat sink has a continuous to the cooling element aligned cooling channel on. This cooling channel of the heat sink causes a Kind of "chimney effect", so that by the warming on the one hand inside the cooling element and on the other hand in the cooling channel a uniform this two components penetrating convection is achieved.

Of Further is due to the additional heat sink in upper end portion of the cooling element a stronger one Cooling in this end region of the cooling element achieved, so that also ensures optimal cooling of the upper LED is. This means that all in the vertical direction consecutive LED are cooled evenly. Especially Be the arranged in the upper end of the cooling element LED through optimal heat dissipation through the heat sink sufficient cooled, so that a thermal overload of this LED is safely excluded.

by virtue of by the aligned to the cooling element or its flow channel arranged cooling channel of the heat sink is the "chimney effect" considerably strengthened allowing a steady flow after the warming of the cooling element and of the heat sink ensured is.

Further advantageous embodiments of the invention are the dependent claims remove.

So can according to claim 2 be provided that the cooling element a plurality, in particular four, flat outer surfaces, on which in each case a circuit board is arranged. By this configuration is in particular a 360 ° round illumination of roads and places safely guaranteed. The LED used each circuit board preferably have in horizontal Direction a beam angle of 120 °, so that their light cone especially at a greater distance from LED bulbs cover in the border areas, which in turn gives a uniform illumination of a subsoil.

Further can according to claim 3 be provided that the cooling channel of the heat sink in its the cooling element opposite axial end portion is formed conically widened. Through this flow direction extended training of the cooling channel in particular, the "chimney effect" is amplified, so that a sufficient convection flow within the cooling element and inside the cooling channel reach the heat sink is. This in turn causes optimal cooling, especially in the upper End region of the cooling element, so that their LEDs can not be thermally overloaded.

According to claim 4 may be provided that the heat sink with a heater and a thermocouple is provided. By this heater is especially at the beginning the switching on of the LED illuminant the "chimney effect" producible. For this purpose, the heat sink to the next heated to a predetermined temperature, so that in the cooling channel the heat sink located Air "rises" and thus the convection current of the air is started by the heating. The temperature increase is monitored by the thermocouple, such that upon reaching a predetermined temperature, this heater is switched off and the convection then runs independently.

Further can according to claim 5 be provided that the heat sink more, outward protruding cooling fins and that the cooling element between the heat sink and a fixed mounting plate is added. By this configuration will provide adequate cooling of the heat sink on the one hand achieved and on the other hand, an optimal thermal coupling between the heat sink and the cooling element. Due to the inclusion of the cooling element between the heat sink and the mounting plate is in case of damage in particular the cooling element Easily exchangeable with its LED.

Further can according to claim 6 be provided that the cooling element through a between the heat sink and the mounting plate fixedly received transparent, substantially cylindrical surrounded by a heat sink is. By this embodiment, in particular a seal of the cooling element achieved with its LED against moisture, so here is an insert outside in a luminaire housing certainly possible is.

Of Further may according to claim 7 a mounting adapter may be provided, which is optional for "standing" or "hanging" mounting of the LED bulb in a light tengehäuse top or bottom is arrangeable and that the LED bulbs through the mounting adapter is held at an axial distance to the lamp housing. Through this Design is particularly ensured that the convection flow within of the cooling element as well as inside the heat sink due the to the luminaire housing spaced mounting of the LED bulb not hindered. In particular, the convection current can after emerge from the heat sink at the top, on the luminaire housing cooling down and outside of the LED bulb to flow down. Due to the "chimney effect" in the cooling element as well as in the heat sink the cooled Air flow in turn sucked from below into the cooling element, so that Here is a circulating convection flow of the cooling air results, creating a optimal cooling the LED is reached.

Further can according to claim 8 be provided that a the LED bulbs at least in the axial Areas of the cooling element arranged LED surrounding reflector is provided. By means of a Such a reflector is in particular an optimal light distribution ensured to the underground.

Around one possible optimal cooling to reach the LED is according to claim 9 provided that the flow channel with inward, at least approximately the entire length of the cooling element provided extending cooling fins is.

Based The drawing is an embodiment of the invention below explained in more detail. there the invention is not limited to the illustrated embodiment be limited. In particular, the heat sink as well the cooling element be designed in another way. It shows:

1 a perspective top view of a heat sink with cooling channel according to the invention;

2 a bottom perspective view of the heat sink 1 ;

3 an axially shortened illustrated cooling element arranged on the outside, provided with a plurality of LED printed circuit boards;

4 a perspective top view of a mounting plate;

5 a perspective sectional view of a fully assembled LED bulb;

6 an LED lamp arranged in a luminaire housing "standing";

7 a perspective view of a "hanging" angeord in a light housing Neten LED illuminant, which is additionally provided with a reflector.

1 shows a perspective top view of a heat sink 1 , which in the present embodiment, a central cooling channel 2 having. This cooling channel 2 penetrates the heat sink 1 completely and is thus open on both sides downwards and upwards. In the surrounding area of this cooling channel 2 has the heat sink 1 a total of four through holes 3 on, over which the heat sink 1 with a cooling element fixed and releasably connectable. For this purpose, connecting screws can be provided with a correspondingly designed screw head (not shown in the drawing), which in the mounted state in conical depressions 21 the through holes 3 sunk into place.

The heat sink 1 is further provided with a plurality of radially outwardly extending cooling fins 4 provided, which in the axial direction of the longitudinal central axis 5 of the heat sink 1 spaced apart from each other. In the lower end, the heat sink points 1 a radially extended retaining bar 6 on.

2 shows a corresponding bottom view of the heat sink 1 , It can be seen that the cooling channel 2 also open at the bottom. The through holes 3 are also out 2 recognizable. In the area of the retaining bar 6 is in the lower end face 7 of the heat sink 1 provided a circumferential receiving groove whose function will be explained later in more detail.

The heat sink 1 from the 1 and 2 is with a cooling element 10 fixed coupled, which, for example, axially shortened in 3 is shown in perspective. This cooling element 10 has in the present embodiment, a substantially rectangular or square cross-section and accordingly forms a total of four flat outer surfaces 11 . 12 . 13 and 14 , On these outer surfaces 11 . 12 . 13 and 14 is each a printed circuit board 15 arranged, which with several axially behind one another LED 16 is equipped.

Instead of a in 3 exemplary provided "single row" arrangement of such LED 16 , a multiple arrangement in several adjacent columns is conceivable.

The circuit boards 15 are in the present embodiment on the outer surfaces 11 . 12 . 13 and 14 screwed. Here, however, an adhesive bond or any other suitable connection is conceivable.

Next is out 3 it can be seen that the cooling element 10 in its corner areas with a total of four, extending over the entire length of the cooling element 10 extending through holes 17 is provided, the arrangement of the through holes 3 of the heat sink 1 equivalent.

Furthermore, it is off 3 it can be seen that the cooling element 10 with several internal cooling fins 18 is provided. Thus, the cooling element forms 10 in its interior a kind of flow channel 19 in which these cooling fins 18 protrude.

It is thus easy to imagine that due to these cooling fins 18 and when flowing through the flow channel 19 with air in the direction of the arrow 20 a cooling effect over the cooling fins 18 is reachable. Because of this flow direction in the direction of the arrow 20 However, it is in the vertical lower portion of the cooling element 10 achieved a greater cooling effect than in the upper end region, since the air flowing through increasingly upwards due to the heat transfer or heat transfer to the cooling fins 18 heated gradually. To also in this upper end of the cooling element 10 ei ne sufficient cooling effect to achieve, is the heat sink 1 from the 1 and 2 intended.

4 shows a perspective top view of a mounting plate 25 on which the cooling element 10 for example, is set up. Accordingly, this mounting plate 25 also a total of four through holes 26 on, leaving the cooling element 10 between this mounting plate 25 and the heat sink 1 from the 1 and 2 is fixed receivable. For this purpose, as already mentioned above, corresponding mounting screws (not shown in the drawing) may be provided. It would also be conceivable that the through holes 17 of the cooling element 10 are provided with internal threads, so that the length of such mounting screws can be made shorter.

Next forms the mounting plate 25 a radially expanded outer mounting flange, which in the present embodiment with four mounting holes 28 is provided.

Furthermore, it is off 4 seen that between the through holes 26 and the mounting holes 28 a circumferential receiving groove 29 is provided. This recording groove 29 serves as well as the receiving groove 8th of the heat sink 1 , For example, a cylindrical envelope body, as below 5 is explained. In order at the cooling element 10 mounted state a convection flow to allow far the mounting plate 25 a central breakthrough 30 on, which in the assembled state in alignment with the flow channel 19 of the cooling element 10 is arranged. Thus, the cooling element 10 fixed between the cooling body 1 and the mounting plate 25 received. In this case, the heat sink 1 a predetermined height of a few cm, so that through the cooling channel 2 with appropriate heating of the heat sink 1 a "chimney effect" can be generated safely.

From the perspective sectional view of 5 it can be seen that the cooling element 10 concentric on the mounting plate 25 is attached. Accordingly, the key breakthrough 30 in the area of the flow channel 19 with its cooling fins 18 arranged. Upper side is on the cooling element 10 the heat sink 1 attached, with its cooling channel 2 in alignment with the flow channel 19 of the cooling element 10 is arranged.

This assembled state of the heat sink 1 as well as the mounting plate 25 on the cooling element 10 is by appropriate screws 31 fixed, which the heat sink 1 , the cooling element 10 as well as the mounting plate 25 project through. It can be provided that the mounting holes 28 ( 4 ) of the mounting plate 25 each with an internal thread (not shown in the drawing) are provided. Next is out 5 an enveloping body 35 recognizable, which on the one hand in the circumferential receiving groove 29 the mounting plate 25 and on the other hand into the circumferential receiving groove 8th of the heat sink 1 is used. It can in the grooves 29 and 8th in each case a seal (not shown in the drawing) may be used, so that the enveloping body 35 on the one hand to the heat sink 1 on the other hand to the mounting plate 25 hermetically sealed. The envelope body 35 consists of a translucent material such as plastic or glass.

Next is out 5 seen that the heat sink 1 between its circumferential cooling fins 4 circumferential grooves 9 forms. In the present embodiment is in one of these grooves 9 a heating element 36 provided by which the heat sink 1 is "preheatable" to a predetermined temperature. By this preheating is in the cooling channel 2 heated air, allowing a convective flow in the direction of the arrow 20 is effected. Thus, this heating element serves 36 for preheating to such a convection flow at the "start" of the LED bulb 40 to effect. For controlling the heating element 36 a not shown in the drawing thermocouple is provided, which is a shutdown of the heating element 36 on reaching a predetermined "limit temperature" causes.

After starting the LED bulb 40 by energizing the LED 16 is heated by this a heating element of the cooling element 10 and thus in the flow channel 19 protruding cooling fins 18 causes. Due to this warming becomes a Konvektionsstrom in the direction of the arrow 20 within this flow channel 19 of the cooling element 10 causes. Because this air from the bottom up in the direction of the arrow 20 heated successively, is in the upper part of the cooling element 10 initially a higher temperature than in the axially lower area. This elevated temperature, which includes the cooling element 10 itself has, is now attached to the heat sink 1 delivered and on the cooling fins 4 emitted to the outside. This means that through the heat sink 1 in the upper end of the cooling element 10 this cooling element 10 is additionally cooled, so that in particular in the axially upper region of the cooling element 10 lying LED 16 again be sufficiently cooled. This is done by the heat sink 1 in the upper end of the cooling element 10 an additional cooling of this cooling element 10 achieved, so that overheating of the arranged in this end region LED is reliably avoided.

Due to the height of the heat sink 1 of a few cm is further through the cooling channel 2 creates a "chimney effect", so that the convection flow in this cooling channel 2 is amplified and thus a suction effect in the flow channel 19 of the cooling element 10 is feasible.

To enhance such suction, the cooling channel 2 upwards in the direction of the arrow 20 also be formed conically widened, as indicated by the dashed lines 42 is shown.

Due to this special design of the LED bulb 40 with its heat sink 1 , its cooling element 10 and through the heat sink 1 caused "chimney effect" can thus be dispensed with an additional electrically operated blower or the like. To optimize cooling, in particular of the cooling element 10 with its applied LED 16 to reach.

To this LED bulb 40 in a luminaire housing 45 ( 6 ) is in the present embodiment, a mounting adapter 46 intended. In the embodiment of the 6 is the LED bulb 40 "Standing" in the luminaire housing 45 arranged. The mounting adapter 46 consists in the present embodiment of a base plate 47 as well as several spacer bolts 48 of which in 6 two pieces are recognizable. This stand plate 47 is for example on the floor plate 49 of the luminaire housing 45 fixed mountable, especially with this base plate 49 screwed. On the spacer bolts 48 is the LED bulb 40 with its mounting plates 25 put on and can with the distance bolts 48 for example, be fixed screwed.

It can be seen that due to this speci ellen design of the mounting adapter 46 the LED bulb 40 in the distance to the bottom plate 49 is held. This remains the key breakthrough 30 ( 4 ) of the mounting plate 25 freely accessible from below, allowing a flow of air through this breakthrough 30 in the cooling element 10 can get. This airflow is in 6 exemplified by the arrows 50 shown. The air flow in the direction of the arrows 50 thus penetrates the cooling element 10 and then the heat sink 1 or its cooling channel 2 up. The from the cooling channel 2 escaping air is in the area of the upper cover plate 51 of the luminaire housing 45 deflected and cooled at the same time.

Furthermore, it can be seen that the luminaire housing 45 in the illustrated embodiment, a circumferential glass body 52 which also for cooling the upward from the cooling channel 2 can serve exiting air. This results in further heating of the cooling element 10 and the heat sink 1 a circulating convection, which in the interior of the cooling element 10 in the direction of the arrows 50 flows upwards and in the environment outside the LED bulb 40 in the direction of the arrows 53 downwards.

Due to the heat sink 1 with its cooling channel 2 caused "chimney effect" is then the air turn below the cooling element 10 sucked, leaving a steady circulating convection in the direction of the arrows 50 and 53 is effected. This is a permanent cooling of the LED 16 on the circuit boards 15 feasible without the need for an additional blower or the like.

Instead of a standing installation position, as in 6 is shown, the LED bulb 40 also in a "hanging" mounting position in a luminaire housing 55 be mounted, as exemplified 7 is recognizable. It is for this purpose the mounting adapter 46 with his distance bolts 48 on the top of the heat sink 1 mounted and screwed with this accordingly. The base plate 47 can do this on an upper mounting plate 56 of the luminaire housing 55 be screwed on. Furthermore, it is off 7 seen that the LED bulb 40 at least in the field of printed circuit boards 15 with an additional reflector 60 may be provided, through which the luminous flux emitted by the LED, for example, downward against the arrow 20 is distractible. The luminaire housing 55 can be open at the bottom or completely closed. Accordingly, between the frame legs 61 and the lower base frame 62 Glass plates tightly inserted, which in 7 are not recognizable.

From the 6 and 7 is further evident that the LED bulb 40 with its cooling element 10 and the heat sink 1 variable in both standing and hanging the arrangement in a light housing 45 respectively. 55 can be used. Due to the special design of both the cooling element 10 as well as the heat sink 1 with its cooling channel 2 is inside the luminaire housing 45 respectively. 55 like this too 6 described a circulating convection through the effect of the "chimney effect" of the cooling channel 2 reached. In that regard, as already mentioned above, can be dispensed with an additional active cooling in the form of a cooling fan. Due to the top-side arrangement of the heat sink 1 on the cooling element 10 Furthermore, a stronger or additional cooling of the upper end portion of the cooling element 10 causes, so that also arranged in this area LED 16 ( 5 ) are sufficiently cooled and thus can not be thermally overloaded.

Claims (9)

LED bulbs ( 40 ) with a tube-like cooling element ( 10 ) on which several with LED ( 16 ) equipped printed circuit boards ( 15 ) are arranged on the outside, wherein the cooling element ( 19 ) substantially in a vertical orientation in a luminaire housing ( 45 . 55 ), characterized in that the cooling element ( 10 ) an inner flow channel ( 19 ) and that the cooling element ( 10 ) in its installation position in the upper end region with a heat sink ( 1 ) is thermally coupled and that the heat sink ( 1 ) a continuous flow channel ( 19 ) of the cooling element ( 10 ) aligned cooling channel ( 2 ) having. LED illuminant according to claim 1, characterized in that the cooling element ( 1 ) several, in particular four, flat outer surfaces ( 11 . 12 . 13 . 14 ), on each of which a printed circuit board ( 15 ) with its LED ( 16 ) is arranged. LED illuminant according to claim 1 or 2, characterized in that the cooling channel ( 2 ) of the heat sink ( 1 ) in its the cooling element ( 10 ) axially opposite end portion flared (dashed line 42 ) is trained. LED illuminant according to one of claims 1 to 3, characterized in that the heat sink ( 1 ) with a heating element ( 36 ) and a thermocouple is provided. LED illuminant according to one of claims 1 to 4, characterized in that the heat sink ( 1 ) a plurality of outwardly projecting cooling fins ( 4 ) and that the cooling element ( 10 ) between the heat sink ( 1 ) and a mounting plate ( 25 ) is fixed. LED illuminant according to claim 5, characterized in that the cooling element ( 10 ) through one between the heat sink ( 1 ) and the mounting plate ( 25 ) fixedly received transparent, substantially cylindrically shaped enveloping body ( 35 ) is surrounded. LED illuminant according to one of claims 1 to 6, characterized in that a mounting adapter ( 46 ), which is optional for "standing" or "hanging" mounting of the LED light source ( 40 ) in a luminaire housing ( 45 . 55 ) can be arranged on the top or bottom side and that the LED illuminant ( 40 ) by the Montageadap ter at an axial distance to the lamp housing ( 45 . 55 ) is held. LED illuminant according to one of claims 1 to 7, characterized in that a LED illuminant ( 40 ) at least in the axial region of the on the cooling element ( 10 ) LED ( 16 ) surrounding reflector ( 60 ) is provided. LED illuminant according to one of claims 1 to 8, characterized in that the flow channel ( 19 ) with inwardly directed, at least approximately over the entire length of the cooling element ( 10 ) extending cooling fins ( 18 ) is provided.