DE202011002138U1 - LED light - Google Patents

Abstract

LED lamp comprising a housing, at least one LED as light source and a lens for guiding the light emitted by the light source,
characterized,
the housing (1) is designed as a frusto-conical heat sink (2) with a large number of cooling fins (4) arranged in the outer wall (3),
in that a frusto-conical large lens (10) with substantially the same volume as the heat sink (2) is provided, and with the small diameter surface (11) of the large lens (10) on the large diameter surface (13) of the heat sink (2 ),
that between the heat sink (2) and the large lens (10), an LED array (21) is arranged with a plurality of LED-s and
that for the heat sink (2) and the large lens (10) the respective large surface (7, 13) comprising, interconnected frame parts (14, 15) are provided.

Description

The innovation relates to an LED lamp comprising a housing, at least one LED as the light source and a lens for guiding the light emitted by the light source.

An LED light of this kind is from the DE 198 34 520 A1 previously known. This has, in the version with an LED, a power of 1 to 5 watts. To increase the power several light sources and optics must be coupled together. There is the problem of cooling the multiple light sources. This is usually done by means of an active cooling device.

The innovation is therefore based on the object to provide an LED lamp of the generic type, which works at significantly higher power without an active cooling device.

To solve this problem, the innovation provides that the housing is designed as a frusto-conical heat sink with a plurality arranged in the outer wall cooling fins that a frusto-conical large lens is provided with a substantially same volume of space as the heat sink and with the small diameter surface of the large lens connects to the large diameter surface of the heat sink, that between the heat sink and the large lens, an LED array is arranged with a plurality of LEDs and that are provided for each of the large diameter, interconnected frame parts for the heat sink and the large lens.

With the frusto-conical heat sink and arranged in the outer wall plurality of cooling fins passive cooling of the LED light is effected, wherein the power loss is dissipated as heat through a strong ribbing of the surface. As a result, the LED light z. B. with a commercial array of 8 × 8 LED's with a power range of about 50 W are formed.

The large lens serves to direct the extreme broad radiation of the LED array (Lambert radiator) and to produce narrow-beam radiation with a half-value angle of 14 °.

In a further development of the invention, it is provided that in the large lens, a sink extending from the small-diameter surface is provided for coupling the light emitted by the LED into the large-size lens.

It is further provided that the heat sink made of aluminum and the large lens made of real glass, PMMA (polymethyl methacrylate) or polycarbonate (PC) are formed.

In a further development of the innovation, it is provided that the small area of the heat sink in diameter about 49.4 mm, the large area of the heat sink in diameter about 116.6 mm and the height about 57.4 mm and the small area of the large lens in diameter about 49.4 mm, the large area of the large lens in diameter about 116.6 mm and the height of the large lens between about 57.4 mm and about 66 mm, since the light exit opening of the large lens is concave.

Finally, it is envisaged according to the innovation that the frame parts for connecting the heat sink to the large lens are formed on the large surfaces surrounding the outside rings, which are held together by means of laterally arranged guide linkage.

The innovation is explained in more detail below with reference to an embodiment of an LED lamp. It shows:

1 : a side view of the LED light

2 : a rear view of the LED light

3 : a soffit of the LED light and

4 : a basic vertical section through the LED light

The LED light includes as housing 1 a frusto-conical heat sink 2 with a variety of outside in the outer wall 3 arranged cooling fins 4 between which are cooling slots 5 are formed. The arranged on the top, in diameter small and flat surface 6 of the heat sink 2 is closed. The large area arranged on the underside 7 of the heat sink 2 is provided with a not shown cooling slots flat lens 8th with a central circular opening 9 Mistake. The heat sink 2 and the lens 8th are made of aluminum. The diameter of the small area 5 of the heat sink 2 is about 49.4 mm. The diameter of the large area 7 of the heat sink 2 is about 116.6 mm. The height of the heat sink 2 is about 57.4 mm. The cooling surface of the heat sink 2 is about 0.25 m.

Below the frusto-conical heat sink 2 is a frustoconical large lens 10 arranged, which has a substantially same volume of space as the frusto-conical heat sink 2 and with their smaller diameter upper surface 11 to the large diameter surface 7 of the heat sink 2 followed.

In the big lens 10 is one of the small upper surface 11 outgoing sink 12 educated. The serving as a light exit opening lower large area 13 the big lens 10 with the large diameter is concave. The big lens 10 is made of real glass, PMMA (polymethyl methacrylate) or polycarbonate (PC). The diameter of the small upper surface 11 the big lens 10 is about 49.4 mm. The diameter of the large bottom surface 13 the big lens 10 is about 116.6 mm. The height of the large lens 10 is between about 57.4 mm and about 66 mm, since serving as a light exit opening bottom surface 13 the big lens 10 is concave.

Both the heat sink 2 as well as the big lens 10 are on the respective outside in the height of the lower large areas 7 respectively. 13 of interconnected frame parts 14 . 15 in the form of rings 16 . 17 clamped the heat sink 2 and the big lens 10 by means of inwardly projecting circumferential webs 18 . 19 hold. The connection of the rings 16 . 17 is done by a laterally mounted guide rod 20 on which both rings 16 . 17 in which the height of the large lens corresponding distance are fixed.

In the area between the top of the large lens 10 passing through the top surface 13 is formed with the small diameter, and the area of the bottom of the heat sink 2 passing through the large area 7 or the lens 9 is formed, is equipped with a variety of LED's LED array 21 stored, with a holder, not shown, inside the heat sink 2 is firmly screwed. In the exemplary embodiment, the LED array comprises 21 a matrix of 8 × 8, ie 64 LEDs, passing through the heat sink 2 by means of laid there, not shown lines from one outside the heat sink 2 arranged, also not shown control unit to be supplied with electrical energy. The controller is on the guide linkage 18 attached. By means of the LED array 2I, a total output of 50 watts can be generated. That from the LED array 21 radiated light is over the sink 12 into the big lens 10 coupled, on the insides of the frustoconical large lens 10 completely reflected and out of the lower, concave surface 13 the big lens 10 broadcast.

The terms "lower and upper surface" refer to the arrangement of the LED lamp on the drawings. Since the LED light can also be rotated arbitrarily, these terms are not mandatory. Also, the LED light can be used without a change in the basic structure as a ceiling light.

LIST OF REFERENCE NUMBERS

1

casing

2

heatsink

3

outer wall

4

cooling fin

5

cooling slot

6

upper small area of 2

7

lower large area of 2

I

end plate

9

central opening in I

10

Great lens

11

small upper surface of 1-0

12

depression

13

large bottom surface of 10

14

frame part

15

frame part

16

ring

11

ring

18

web

19

web

20

guide linkage

21

LED array

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 19834520 A1 [0002]

Claims (6)

LED luminaire comprising a housing, at least one LED as light source and a lens for guiding the light emitted by the light source, characterized in that the housing ( 1 ) as a frusto-conical heat sink ( 2 ) with a plurality in the outer wall ( 3 ) arranged cooling ribs ( 4 ) is formed such that a frusto-conical large lens ( 10 ) with a substantially same volume as the heat sink ( 2 ) is provided, and with the small diameter surface ( 11 ) of the large lens ( 10 ) to the large diameter surface ( 13 ) of the heat sink ( 2 ) connects that between the heat sink ( 2 ) and the large lens ( 10 ) an LED array ( 21 ) is arranged with a plurality of LED s and that for the heat sink ( 2 ) and the large lens ( 10 ) the large area ( 7 . 13 ) comprehensive, interconnected frame parts ( 14 . 15 ) are provided. LED light according to claim 1, characterized in that in the large lens ( 10 ) one of the small diameter surface ( 11 ) of the large lens ( 10 ) outgoing sink ( 12 ) for coupling the LED of the LED array ( 21 ) radiated light into the large lens ( 10 ) is provided. LED lamp according to one of claims 1 or 2, characterized in that the heat sink ( 2 ) made of aluminum and the large lens made of real glass, PMMA (polymethyl methacrylate) or polycarbonate (PC) are formed. LED light according to one of claims 1 to 3, characterized in that the small area ( 6 ) of the heat sink ( 2 ) in diameter about 49.4 mm, the large area ( 7 ) of the heat sink ( 2 ) in diameter about 116.6 mm and the height of the heat sink ( 2 ) be about 57.4 mm. LED light according to one of claims 1 to 3, characterized in that the small area ( 11 ) of the large lens ( 10 ) in diameter about 49.4 mm, the large area ( 13 ) of the large lens ( 10 ) in diameter about 116.6 mm and the height of the large lens ( 10 ) be between about 57.4 mm and about 66 mm, since the serving as a light exit opening large area ( 13 ) of the large lens ( 10 ) is concave. LED lamp according to one of claims 1 to 5, characterized in that the frame parts ( 14 . 15 ) for connecting the heat sink ( 2 ) with the large lens ( 10 ) from these on the large areas ( 2 . 13 ) surrounding rings ( 16 . 17 ) are formed, which by means of a laterally arranged guide link ( 20 ) are held together.

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