DE202010013172U1 - LED light with heat sink - Google Patents

Abstract

LED light (1) with
a carrier (2) with connection contacts for at least one light-emitting diode (3) and with
a heat sink (5), which is heat-conductively connected to the carrier (2),
characterized in that
the heat sink (5) is of planar shape and has a plurality of recesses (6).

Description

The present invention relates to an LED luminaire with a heat sink according to the preamble of patent claim 1.

After the conventional incandescent lamps have been replaced by the so-called energy-saving lamps (compact fluorescent lamps) in the European market, LED lamps are already being discussed as their successor. For easy replacement of incandescent bulbs energy saving lamps were provided with the typical incandescent electrical contact with external thread, the screw base, and visually brought into a shape to fit in the variety of commercially available lights. The disadvantage of energy-saving lamps is that they require electronic ballasts, which are usually installed directly in the lamp socket. Advantages of energy-saving lamps compared to incandescent lamps are the longer service life, the lower energy requirement with the same light output and the significantly lower heat development. Disadvantages, in turn, are the higher purchase price, the technically more difficult to implement dimmability and the often perceived as unnatural light color of the energy-saving lamps.

More advantages over conventional incandescent bulbs, however, promises the LED lighting, d. H. the lighting with LEDs. ("Light Emitting Diodes", abbreviated LED). LEDs consume even less energy than energy-saving lamps because they convert the absorbed energy predominantly into light (semiconductor transitions) and hardly into heat. They have much smaller dimensions than energy-saving or incandescent lamps and far exceed the life of conventional lamps. Ever since a white glowing LED lighting has been made economically feasible, the use of LED lighting in everyday life is basically no longer an obstacle. For this purpose, the LED bulbs must be optimized only in terms of the size of the illuminated fields and the direction of this field radiant intensity, since the very high luminance of the LEDs can adversely affect glare as noticeable. The initial cost of LED bulbs are still relatively high. Using red, green and blue LEDs, almost all colors including white light can be generated for the eye. However, for reasons of cost, white LEDs are based on a blue chip that is coated with a phosphor that converts the blue light into white light.

As a substitute for the incandescent lamp or the energy-saving lamp today are so-called retrofit LED bulbs with the typical screw or plug contacts in the trade. Such LED lights usually comprise a plurality of LEDs, which are arranged on a support (support plate, circuit board, board), wherein the carrier in turn is integrated in a reflector-like luminaire geometry, which predominantly acts as a heat sink. Since light emitting diodes convert a part of the supplied electrical energy into heat, the carrier serves not only for power supply, but also for heat dissipation. For this purpose, the carrier is in turn connected to a heat sink in a heat-conducting manner. Effective heat dissipation is important not only for a consistent spectral composition of the radiated light and for a constant efficiency (luminous efficiency in lumens / watt), but also for the long life of a light-emitting diode, which can currently amount to more than 50,000 operating hours (compared to incandescent lamps with lifetimes of about 1,000 hours or fluorescent lamps of about 10,000 hours).

In order to achieve the principally possible long service life of the LEDs, it is, as already mentioned, necessary to dissipate the generated heat effectively and to keep the LEDs at a constant, low temperature level. Since LEDs, unlike incandescent lamps, are not directly cooled by heat radiation, the heat must be removed by heat conduction followed by convection and heat radiation. Usually, the heat conduction takes place via the connected heat sink and the convection in the form of free convection in the ambient air. Forced convection produced by blowers should be avoided.

From the DE 20 2009 003 105 U1 an LED lamp with a heat sink is known, which has a rectangular base, on which an LED multi-chip is applied heat-conducting, perpendicular to the LED multichip facing away from the surface of the base rectangular projections (bars) extend, which dissipate the heat and to promote convection.

From the DE 10 2007 008 838 A1 is also an LED lamp with a plurality of LED components, which are mounted on a printed circuit board, known, wherein the LED components are directly or indirectly connected to a heat sink. In one possible embodiment, the printed circuit board is connected to conically shaped walls which surround the underside of an LED component. In these conical walls engage frustoconical projections formed, which are located on the basis of the heat sink. On the opposite side of this base are mounted perpendicular to the base and mutually parallel cooling fins. While the conical walls are to act as "heat spreaders", the cooling fins serve as a "heat sink". By this comparatively complicated construction, the heat conduction should be improved, while the convection is mediated by conventional cooling fins.

A construction for an LED lamp with a heat sink, in which a cooling liquid for heat transfer from an LED to the heat sink is used, is from the DE 10 2008 005 697 A1 known. Also this construction seems expensive. The heat sink used in turn uses cooling fins, which should convey the convection.

A problem with the known heat sinks with their cooling fin or lamella construction is that the surrounding air can not penetrate sufficiently into the fin or fin gaps. Frequently, the heatsinks mimic previously customary reflector geometries, so that the air flows around the outer contour rather than penetrating into the intermediate spaces. Frequently, the distance of the fins or ribs is lowered in order to achieve a high number of fins or ribs can. If the level is too close, air flow is hindered by boundary layer effects and convection is prevented. In addition, outgoing heat radiation only affects adjacent lamellae or ribs, so that heat radiation can scarcely contribute to heat dissipation.

Against this background, in the present case, the task to improve the cooling of an LED light, with effort and cost to be minimized.

This object is achieved by an LED lamp according to claim 1.

In the LED lamp according to the invention. with a carrier with connection contacts for at least one light emitting diode and a heat sink, which is thermally conductive with the carrier in communication, the heat sink has a planar shape and a plurality of recesses or openings.

It has surprisingly been found that a dergestalter heat sink can contribute much more to the cooling of the LEDs than previously known, fins, rods or ribs having heat sink. In addition, a flat heat sink with a plurality of recesses is technically simple and thus inexpensive to produce. The increased heat dissipation can be explained by the fact that a higher heat radiation can take place from the heat sink, and that, moreover, unimpeded free convection is possible. This convection is likely due to vortex formation at the recesses contribute more to a heat transfer than the slow laminar air flow between cooling fins.

It is advantageous if the carrier which supplies the light-emitting diodes electrically is arranged essentially in a surface center of the heat sink. In this way, the carrier in the lateral direction is as evenly as possible surrounded by the heat sink surface, so that a homogeneous removal of heat can take place.

Furthermore, it is advantageous if the heat sink has a planar shape, in which case a circular or polygonal shape is preferred. Optimal homogeneity of the heat dissipation provides a circular shape when the carrier is arranged with its center of area in the center of the circle. The shape of the heat sink can follow technical aspects as well as design considerations.

In another advantageous embodiment, the heat sink is curved and in particular has a reflector-like shape. In addition to the actual task of cooling, a curved heat sink can take on the additional task of radiating the light emitted by the light-emitting diodes as homogeneously as possible in a defined spatial area. Possible domed geometries are a cone or cylinder shell or a paraboloid or hyperboloid. Such geometries are often used for reflector geometries. At the same time, the glare effect of the light-emitting diodes can be reduced as a result and, in addition, the installation space required for the LED light according to the invention can be reduced. Because of the curved geometry, more heat sink material can be used with the same lateral expansion.

The heat sink is preferably made of a good thermal conductivity material, such as copper or aluminum.

The recesses are in particular circular and can, for example, be arranged equidistant from one another at least in a plane direction.

For optimal heat dissipation by free convection of the heat sink within the LED light is arranged such that the recesses are freely flowed through by ambient air.

The invention further relates to a lamp with the LED lamp according to the invention. In this case, a lamp is understood to be an operational lighting unit which comprises the LED lamp according to the invention and generally has a reflector which directs the emitted light onto a surface to be illuminated.

It should also be noted that the carrier with the connection contacts for at least one light-emitting diode, which is also referred to as a printed circuit board or board, already be part of the heat sink itself. As a rule, however, the carrier is connected to the heat sink in a heat-conducting manner (eg by soldering, gluing, screwing on).

It should be noted that the features of the invention described above and to be described can be used not only in the described combination but also in other combinations or alone, without departing from the scope of the invention.

The invention and its advantages will be explained in more detail below with reference to an embodiment illustrated in the figures.

1 shows an LED lamp according to the invention in a perspective view.

2 shows the LED light off 1 in another perspective view.

3 again shows a different view of the LED light 1 ,

4 shows another embodiment of an LED lamp in perspective view.

1 shows a preferred embodiment of an LED light 1 with a carrier 2 with light emitting diodes electrically connected thereto 3 (here four pieces) and with a heat sink 5 , which conducts heat with the carrier 2 communicates. In the present case, the connection is made by gluing. The heat sink shown is flat and has a circular shape (disc). The (also circular) carrier 2 is concentric to the heat sink 5 arranged. The heat sink 5 is made of a thermally conductive material, such as aluminum or copper, with numerous recesses 6 manufactured. In a particularly simple manner, the heat sink can be realized as a circular section of a commercially available perforated plate. Of course, other, in particular higher-quality alternatives can be provided in which higher-grade heat-conducting materials and / or differently shaped recesses 6 are provided. One of the conventional light bulbs known screw base 7 serves for connection to the electrical supply. The on the carrier 2 existing electronics (capacitors, resistors, etc.) is included 4 designated. The light-emitting diodes 3 are in this case uniform along the circumference of the circular support 2 distributed. Of course, other arrangements of such LEDs are known and possible in the context of the present embodiment.

The 2 and 3 show other perspective views of the LED light 1 out 1 , The explanations to 2 and 3 correspond in the same way to those from 1 , so that a repetition can be omitted here.

While using conventional heatsink with ribs or fins a temperature at the light emitting diodes 3 on the carrier 2 was measured from about 75 ° C, it succeeded using the heat sink shown 5 to lower this temperature by 20 ° C to a temperature of about 55 ° C. This proves the better heat dissipation due to increased heat radiation and convection.

The designed as a flat disc heat sink 5 creates space for a high air movement up to the base of the LED light. In particular, air may be in the outer ring segment of the heat sink 5 which extends in the radial direction to the carrier 2 connects, through the recesses 6 move. On the short path of the disk flow there are no cross-sectional narrowing boundary layers. The heated after contact with the disc air can flow almost unhindered upwards. Furthermore, heat radiation can take place over a large area and unhindered on both sides of the disk into the room.

The temperature reduction of the light emitting diodes and thus the cooling can be optimized over the thickness of the flat heat sink (the sheet metal thickness in the perforated plate), on the distance between the recesses and on the diameter of these recesses. With increasing thickness, the heat sink surface acts as a larger heat conductor, which can thus better transport heat away from the light-emitting diodes (heat conduction). About the distance and the diameter of the recesses 6 can heat radiation into the room as well as convection by means of the recesses 6 adjusted by flowing air and thus optimized.

4 finally shows a further embodiment of the LED light 1 with an octagonal flat heat sink 5 , The explanations apply to 1 and 2 in an analogous way. While in the 1 . 2 and 3 circular or octagonal heat sink surfaces are shown, which allow a particularly homogeneous heat dissipation away from the center, other geometries are conceivable, which may also be chosen from a design point of view.

From the figures, it can be seen that the planar geometry shown there can easily be changed into a curved geometry. For this purpose, for example, the heat sink in the edge region in the axial direction "pulled", whereby the heat sink assumes, for example, paraboloidal shape. Such a shape has reflector effect; at the same time more Kühlkorpermaterial can be used for cooling. This variant thus still improves the in the 1 to 4 illustrated embodiments to the improved heat dissipation and the additional function of the reflector.

LIST OF REFERENCE NUMBERS

1

LED light

2

carrier

3

led

4

electronics

5

heatsink

6

recess

7

sCREW

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 202009003105 U1 [0006]
• DE 102007008838 A1 [0007]
• DE 102008005697 A1 [0008]

Claims (10)

LED light ( 1 ) with a carrier ( 2 ) with connection contacts for at least one light-emitting diode ( 3 ) and with a heat sink ( 5 ), which conducts heat with the carrier ( 2 ), characterized in that the heat sink ( 5 ) is of planar shape and a plurality of recesses ( 6 ) having. LED light according to claim 1, characterized in that the carrier ( 2 ) substantially in a surface center of the heat sink ( 5 ) is arranged. LED lamp according to claim 1 or 2, characterized in that the heat sink ( 5 ) has a flat shape. LED light according to claim 3, characterized in that the heat sink ( 5 ) has circular or polygonal shape. LED light according to claim 1 or 2, characterized in that the heat sink is curved, in particular reflector-like shape. LED light according to one of claims 1 to 5, characterized in that the heat sink ( 5 ) is made of a thermally conductive material, in particular of copper or aluminum. LED light according to one of claims 1 to 6, characterized in that the recesses ( 6 ) are circular. LED light according to one of claims 1 to 7, characterized in that the heat sink ( 5 ) within the LED light ( 1 ) is arranged such that the recesses ( 6 ) can be flowed through by ambient air. LED light according to one of claims 1 to 8, characterized in that the recesses ( 6 ) are equidistant from each other at least in one surface direction. Lamp with an LED light ( 1 ) according to one of claims 1 to 9.

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