WO2016184775A1

WO2016184775A1 - Led lamp

Info

Publication number: WO2016184775A1
Application number: PCT/EP2016/060699
Authority: WO
Inventors: Bernd Beisse
Original assignee: Bernd Beisse
Priority date: 2015-05-15
Filing date: 2016-05-12
Publication date: 2016-11-24
Also published as: DE202015102507U1; EP3295234A1

Abstract

The invention relates to an LED lamp (1), in particular an LED spotlight, comprising a lamp housing (2), at least one LED (3), which is arranged in the lamp housing (2) and, in particular, has a planar extent, and a first lens (5), which is arranged at a distance from the LED (5) in a first receptacle (4) of the lamp housing (2), wherein, after the first lens (5), a second lens (8) is arranged in a second receptacle (9) of the lamp housing (2), wherein the diverging light beam emitted by the LED (3) is converged in the first lens (5), enters the second lens (8) as a diverging light beam, and exits the second lens (8) as a converging light beam.

Description

LED light

The present invention relates to an LED light, in particular an LED spotlight according to the preamble of claim 1.

Technological background

An LED luminaire has a light-emitting diode as a light-emitting diode in the form of a light-emitting semiconductor component. The specific selection of semiconductor materials and doping can be used to vary the properties of the generated light. Also so-called white light can be generated and is used in particular for so-called spotlights. The problem of spotlights with an LED lamp, however, is that on the one hand a Lichtentmischung can occur, on the other hand, the glare angle is very small, i. LED lights are often distracting due to the glare effect. For this reason, in the past, very deep housings for LED spotlights have been used to increase the glare angle.

In the case of the spotlight emitters, in addition to a multiplicity of hybrid forms, two essential types of construction can be distinguished. In a first, larger design, a plurality of super bright LEDs are usually arranged side by side as a flat light source whose light is concentrated by means of a reflective or refractive optical system on a common illumination area.

A second design uses a single LED or high-power LED, from which a surface-emitted light beam, usually with an opening angle of at least 120 °, is emitted. For use in the spotlight emitter, the large aperture angle of the light beam is collected by means of a reflector or a lens. This design is particularly suitable For small and inconspicuous spotlights, such as those used in showcases or shop windows. A particularly compact and lightweight design can be achieved if aspherically shaped lenses are used for collecting the light beam, which are preferably made of plastic.

In the case of the LED luminaire disclosed in DE 10 2008 005 120 A1, a plastic lens is used in combination with a reflector in order to improve the emission behavior of the LED. The plastic lens may also be aspherical in shape and is spaced from the LED. The reflector deflects light transmitted to the lens into the illumination region of the light beam collimated by the lens.

In the illumination device known from DE 10 2010 004 825 A1, an aspheric lens is divided axially into a plurality of optical regions, which consist of glasses of different refractive index, for selectively influencing the optical properties of the light of the LED.

Nearest prior art

An LED lamp according to the preamble of claim 1 is known from DE 20 2014 103 713 U1. In this LED luminaire, the aspherical lens is designed to correct the chromatic aberration such that it comprises at least one diffractive structure with a resulting structure depth and a structurally-effective optically effective surface, based on chromatic aberrations of the LED emitted and the aspherical lens illustrated light beam has a corrective effect. To avoid glare, however, it is still necessary to use the LED light very deep in the luminaire housing in such LED lights. Object of the present invention

The object of the present invention is to provide an LED lamp of the generic type, in particular using LEDs with high light output available, which allows a particularly flat design, but at the same time has a high glare angle.

Solution of the task

The above object is solved by the teaching of claim 1. Advantageous embodiments are claimed in the dependent claims.

According to the invention, after the first lens, a second lens is arranged in a second receptacle of the luminaire housing, wherein the diverging light beam emitted by the LED is collimated in the first lens, enters the second lens as a diverging light beam, and leaves the second lens as a converging light beam. It is thereby achieved that, in the case of an LED, in particular one with high light powers, on the one hand a low glare results, i. a high glare angle is achieved, on the other hand also a good accentuation of illuminated areas is made possible. In addition, a light mixture with a high degree of homogenization and a light beam with soft edges is achieved, despite the accentuation of the light beam. It can be used comparatively flat designs of luminaire housings. The two lenses allow in their interaction a determination of the beam angle.

Conveniently, the LED lamp according to the invention has no reflector. As a result, the housing construction can be simplified. At the same time, a particularly flat design of the LED light can be achieved. Advantageously, the distance of the first lens to the LED or the second lens is changeably adjustable. As a result, the emission angle of the LED, which is usually 120 ° and determines the size of the emergent cone of light, can be adjusted, in such a way that the light beam leaving the LED impinges optimally on the second lens. At the same time this measure ensures adaptability of the luminaire also with respect to LEDs of different surface design.

Appropriately, the variability of the distance of the LED to the first lens is structurally made possible by the fact that the first lens can be screwed into the lamp housing. By individual choice of the screw-in the desired distance can be adjusted in a simple manner.

The embodiment according to claim 5 ensures a particularly simple construction with a reduced number of parts. This also makes a very simple installation of the LED possible.

The construction further has the advantage that a fixation of the retaining ring is carried out in a simple manner exclusively by magnetic attraction. For this purpose, for example, be arranged along the circumference of the retaining ring in corresponding recesses a plurality of magnets which hold the retaining ring in position. To open the LED light only the magnetic holding force must be overcome by lifting the retaining ring. The second lens can then be easily removed and the position of the first lens changed by screwing.

Conveniently, the first lens is formed as an aspherical lens. As a result, a particularly good color homogenization is achieved. The LED luminaire according to the invention preferably has a glare angle of at least 60 °, preferably of at least 65 °, particularly preferably of at least 70 °. This makes it possible, on the one hand particularly accentuated On the other hand, the observer can approach the light spot without being blinded by the latter. Preferably, the convergence angle of the converging light beam is at most 20 °, preferably at most 16 °. As a result, very good light accentuations can be set with the LED lamp according to the invention.

Description of the invention with reference to embodiments

An expedient embodiment of the LED lamp according to the invention is explained in more detail below with reference to drawings. Show it:

Fig. 1 is a greatly simplified partial sectional view of the invention

LED lamp in which the first lens is in a first position; Fig. 2 is a greatly simplified partial sectional view of the LED lamp of FIG. 1 with a first lens at a different distance to the LED and

Fig. 3 is a greatly simplified schematic representation of the light emitted by the LED lamp according to the embodiments of Fig. 1 and Fig. 2 light beam.

Reference numeral 1 in Fig. 1 denotes the LED lamp according to the invention in its entirety. It comprises a luminaire housing 2, which has cooling ribs 6, which are preferably arranged completely on the outside of the luminaire housing 2. The luminaire housing 2 is preferably made of metal. Inside the lamp housing 2 is a (not shown) board arranged with a arranged at the top, preferably flat, LED 3. The LED 3 has (not shown) electrical connections for the supply of electrical energy. The board is fastened to the inside of the luminaire housing 2 via screws (not shown).

Furthermore, the LED lamp 1 according to the invention comprises a first lens 5, which collimates the light beam leaving the LED 3 with a high emission angle (for example 120 °). The first lens 5 is preferably designed as an aspherical lens and can be positioned at a variable distance from the LED 3 within the luminaire housing 2. For this purpose, the inside of the lamp housing 2 has an internal thread 14 into which a threaded ring 16 connected to the first lens 5 engages with an external thread 15. The threaded ring 16 is fixedly connected to the first lens 5, preferably glued. By changing the screw-in position, it is possible to adjust the position and thereby vary the emission angle of the light beam.

The screw connection preferably has play in order to be able to compensate for changes due to thermal expansion, so that a slight screw connection also remains possible over different temperature ranges.

The rear side 17 of the first lens 5 expediently has a light matting in order to justify a light mixture. The luminaire housing 2 has an inner surface 7 which widens outwards from the first lens 5, at the outer end region of which a first circumferential step 11 is provided into which a peripheral edge 8a of a second lens 8 can be inserted. Furthermore, the luminaire housing 2 has a second circumferential step 12, which is provided to receive a retaining ring 10, preferably flush with the underside of the luminaire housing 2. The circumferential edge 8a of the second lens 8 is in the inserted state below or at least flush with the recess 12 and is fixed in the region of an outer circumferential step 8b of the second lens 8 of the retaining ring 10 on the outside.

In the region of the circumferential recess 12, a plurality of magnets 13 are accommodated in recesses on the lamp housing 2 along the circumference, with the aim of holding the retaining ring 10 on the lamp housing 2 in position.

By the aforementioned construction, the second lens 8 can be easily removed or re-mounted. Likewise, if necessary, a rapid change in the axial position of the first lens 5 can be made.

As can be seen from FIGS. 1 and 2, the first lens 5 can be arranged in the one case at a further distance from the LED 3 (FIG. 1) or also at a closer distance if required (FIG. 2). The positional adjustment of the first lens 5 serves to bundle the light beam of the LED 3 in such a way that the light beam of the LED 3 impinges optimally on the second lens 8.

As can be seen from FIG. 3, the light beam leaving the LED 3, which is, for example, an emission angle of 120 °, is bundled by the first lens 5 to an emission angle of, for example, 60 °. The second lens 8 focuses this light beam to an emission angle of, for example, a maximum of 20 °, preferably for example a maximum of 16 °, as can be seen in FIG. 3. The glare angle α achieved by the lens combination amounts to a maximum of 60 °, preferably a maximum of 65 °, particularly preferably a maximum of 70 °. In the variant shown in Fig. 3, the glare angle is 70 °.

The invention makes it possible to achieve illumination spots with a very high glare angle with LEDs of very high luminance (for example, up to 2000 lumens) with a low overall depth of the luminaire housing. Furthermore, the light has a very high color homogeneity. The luminaire housings are particularly easy to produce and inexpensive to operate / repair. REFERENCE LIST

1 LED light

2 luminaire housing

3 LEDs

4 only recording

5 first lens

6 cooling fins

7 inside surface

8 second lens

8a circumferential edge

8b outer circumferential step

9 second shot

10 retaining ring

11 first circumferential step

12 recess

13 magnet

14 internal thread

15 external thread

16 threaded ring

17 back side

Claims

PAT E N TA N S RÜ C H E

LED light (1), in particular LED spotlight, with a light housing (2),

at least one LED (3) arranged in the lamp housing (2), in particular with a flat extension,

a first lens (5) arranged at a distance from the LED (5) in a first receptacle (4) of the lamp housing (2), characterized in that

After the first lens (5), a second lens (8) is arranged in a second receptacle (9) of the lamp housing (2), whereby

the diverging light beam emitted by the LED (3) is collected in the first lens (5),

enters the second lens (8) as a diverging light beam, and

the second lens (8) leaves as a converging light beam.

LED light according to claim 1, characterized in that

Light housing

(2) has no reflector between the LED (3) and the first lens (5).

LED light according to claim 1 or 2, characterized in that the distance between the LED

(3) and the first lens (5) can be changed.

4. LED lamp according to at least one of the preceding claims, characterized in that the first lens (5) can be screwed into the lamp housing (2).

LED lamp according to at least one of the preceding claims, characterized in that the second lens (8) has a circumferential edge (8a) which rests on a first circumferential step (1 1) of the lamp housing (2), the second lens (8 ) further has an outer circumferential step (8b), a retaining ring (10) is provided, which is arranged in a second circumferential step (12) of the lamp housing (2) and which rests on the step (8b) of the second lens (8). and so the second lens (8) is fixed on the lamp housing (2). 6. LED light according to claim 5, characterized in that the

Retaining ring (10) is fixed to the lamp housing (2) by means of magnetic attraction.

LED lamp according to claim 6, characterized in that a plurality of magnets (13) are arranged along the circumferential recess (12) of the lamp housing (2).

LED light according to at least one of the preceding claims, characterized in that the first lens (5) is designed as an aspherical lens.

LED lamp according to at least one of the preceding claims, characterized in that the glare angle of the LED lamp (1) is at least 60°, preferably at least 65°, particularly preferably at least 70°.

10. LED lamp according to at least one of the preceding claims, characterized in that the convergence angle of the converging light beam is at most 20 °, preferably at most 16 °.