DE102012203941A1 - LED lighting device such as task light, comprises several LEDs, an anti-glare optic for preventing glaring of groups of LEDs or individual LED, and a diffuser optic which is arranged between the LEDs and the anti-glare optic - Google Patents

Abstract

The LED lighting device (11) comprises several LEDs (12), and an anti-glare optic (19) for preventing glaring of groups of LEDs or individual LED. A diffuser optic (17) is arranged between the LEDs and the anti-glare optic. The anti-glare optic comprises several light transmission openings (20) which are associated with the corresponding LEDs. The light transmission openings are configured as hollow reflectors for the associated LEDs. The diffuser optic comprises a diffuser cover having convexities (18), which is arranged above the LEDs.

Description

The invention relates to an LED lighting device with a plurality of light-emitting diodes and an anti-glare optics, which glare the light-emitting diodes at least in groups, in particular individually. The LED lighting device can be used in particular as a workstation lamp, in particular a ceiling lamp or suspended luminaire, or as a part thereof, e.g. as an LED module.

By using a plurality of low power LEDs which are individually deblasted, simple LED luminaires with a very low overall height can be provided. Since the main part of the light emitted by the LED light is neither mirrored nor diverted in any other way, very efficient structures are possible. The direct radiation of several LEDs, however, basically brings with it the disadvantage of multiple shading, which is perceived by a viewer as subjectively unpleasant.

The multiple shading can be avoided by lights, which are equipped with prism plates instead of a glare-proofing. However, these are far more expensive and many times more complex in construction.

It is the object of the present invention to overcome the disadvantages of the prior art at least partially and in particular to provide an LED lighting device with anti-glare optics, in which a multiple shading can be reduced with comparatively simple means.

This object is achieved according to the features of the independent claims. Preferred embodiments are in particular the dependent claims.

The object is achieved by an LED lighting device comprising a plurality of light-emitting diodes, a glare-suppressing optics which at least in groups deblasts the light-emitting diodes, and a diffuser optic arranged between the light-emitting diodes and the glare-suppression optics.

By means of the diffuser optics, the light emitted by the light-emitting diodes is scattered before passage through the anti-glare optics and thereby diffusely distributed. The thus enlarged luminous area before the passage through the anti-glare optics sharp edged Schattenwürfe be softened ("blurred") and avoided at least to a significant extent. In particular, a multiple shading can be reduced thereby.

This LED lighting device has the advantage that it allows a glare-free structure with a pleasant shadow. In addition, a greater homogeneity of the light emitted by the LED lighting device can be achieved by the interaction of anti-glare optics and diffuser optics. This LED lighting device is also inexpensive realizable.

The diffuser optics is thus in particular optically downstream of the light-emitting diodes. In particular, the diffuser optics can be a (common) diffuser optics connected in series to all light-emitting diodes. The diffuser optics may in particular consist of translucent plastic, which has light-scattering filling material.

The anti-glare optics are in particular optically downstream of the diffuser optics. In this case, light which has passed through the diffuser optics can, in particular, partly run directly through at least one light passage opening and partly strike the glare-proofing optics. In particular, light striking the anti-glare optic can be reflected in a diffuse or specular manner.

The anti-glare optics and / or the diffuser optics can be designed in one piece or in several parts.

The fact that the anti-glare optics blinding the light-emitting diodes, at least in groups, may in particular mean that the anti-glare optics bleaches a plurality of light-emitting diodes arranged in groups or together. In particular, these multiple light emitting diodes can shine in the same color or in different colors. A color may be monochrome (e.g., red, green, blue, etc.) or multichrome (e.g., white). In particular, the plurality of light emitting diodes arranged in groups may produce a mixed light, e.g. a white mixed light. The plurality of light-emitting diodes arranged in groups can furthermore be equipped with a common beam guidance optics, e.g. a diffuser or a lens, and so on.

It is an embodiment that the anti-glare optics individually blinding the LEDs. As a result, a particularly high glare-reduction effect is achieved.

In general, a light-emitting diode may contain at least one wavelength-converting phosphor (conversion LED). The phosphor may alternatively or additionally be arranged remotely from the light-emitting diode ("remote phosphor"). A light-emitting diode may be in the form of at least one individually packaged light-emitting diode or in the form of at least one LED chip. Several LED chips can be mounted on a common substrate ("submount"). The at least one light-emitting diode can with at least one own and / or common Optics be equipped for beam guidance, for example, at least one Fresnel lens, collimator, and so on. Instead of or in addition to inorganic light-emitting diodes, for example based on InGaN or AlInGaP, it is generally also possible to use organic LEDs (OLEDs, for example polymer OLEDs).

The number of light emitting diodes is not limited and may for example be between three and 1000, in particular between six and 500, in particular between ten and 100.

It is still an embodiment that the anti-glare optics has a plurality of light passage openings, which are each arranged above an associated or associated at least one light-emitting diode. Thus, a high luminous efficacy can be maintained since the light emitted by the respective light-emitting diode can pass through the diffuser optics and through the respectively associated light passage opening.

It is yet a further embodiment that the light transmission openings are designed as reflectors, in particular hollow reflectors, for the respectively associated or associated at least one light-emitting diode. This can improve glare even further and enables a diverse design of a Lichtabstrahlmusters. A reflector surface may in particular be formed by a circumferential side wall of the respective light passage opening.

In particular, the reflector surface may be designed so that it specifically reflects the light impinging on it in a direction which differs from the main emission direction of the associated LED, in particular into an edge region of an associated light cone. As a result, a more uniform brightness distribution of the light emission pattern emitted by the LED lighting device can be achieved.

It is a development that the light transmission openings or their reflector surface in plan view are circular, honeycomb-shaped (for example hexagonal) or rectangular. This can allow a high packing density and a particularly good suppression of multiple shading.

The reflector surface may be specular, e.g. by being coated with a reflective layer, e.g. made of or with silver and / or aluminum, or by a high-gloss finish. Alternatively, the reflector surface may be designed diffusely reflecting, e.g. by a white coloring, e.g. through a layer of titanium oxide.

The reflector surface may generally be designed differently than the surrounding surface of the anti-glare optics, e.g. in terms of surface texture and / or color, etc.

It is yet another embodiment that the diffuser optics is a diffuser disk with bulges arranged above the at least one light-emitting diode. Due to the bulges, a diffuse light distribution can practically be limited to the area of the bulge (for example, with the exception of low residual light portions), which allows a sufficient broadening of the light emission surface and still maintains a certain brilliance due to the local boundary (in contrast, for example, to a large-area diffuser). , As a result, a passage of light through undesired regions of the diffuser optics, e.g. be suppressed below closed areas of the anti-glare optics, which in turn supports a high light output. Furthermore, such a particularly flat structure can be achieved.

It is also an embodiment that the bulges protrude into an associated light passage opening of the anti-glare optics. Thus, light losses can be suppressed particularly effectively, and it can be achieved a particularly flat structure. However, in principle, the bulges can be dispensed with and e.g. a flat diffuser disk can be used.

It is also an embodiment that the LEDs are applied to a front side of a common substrate, a back side of the substrate is connected to a heat sink, the diffuser optics rests on the front side of the substrate and the anti-glare lens rests on the heat sink. This embodiment has the advantage that a large-area and thereby flat LED lighting device with a simple structure can be provided in a simple manner.

The substrate may, for example, be a ceramic substrate, in particular when the LEDs are designed as LED chips. The substrate may also be designed as a printed circuit board.

The heat sink may in particular also be regarded or configured as a base of the LED lighting device, and the anti-glare optical system may in particular correspond to a cover.

It is also an embodiment that the cooling body protrudes laterally beyond the substrate, the anti-glare lens rests on at least one laterally projecting region of the heat sink and presses the anti-glare optics on the diffuser optics. This allows, firstly, an effective articulation of the glare-proofing to the heat sink and second, an effective contact pressure or pressing of the Diffuser optics to the substrate, whereby the substrate is in turn pressed against the heat sink, which allows a fixed arrangement and good heat transfer in relation to the heat sink.

It is still an embodiment that the diffuser optics is at least partially guided to an outside, in particular lateral edge, the LED lighting device.

It is yet another embodiment that the LED lighting device has an at least partially up to an outside, in particular lateral edge, the LED light device guided optical fiber, which is optically coupled to the diffuser optics. As a result, a side and / or effect lighting can be provided by means of (residual) light, which propagates laterally in the diffuser optics and would otherwise be lost.

It is also an embodiment that the light guide is arranged laterally, in particular laterally encircling, the diffuser optics.

It is a further development that the light guide is arranged at least in regions, in particular laterally encircling, between the heat sink and the anti-glare optics.

It is still a further development that the light guide is pressed by means of the anti-glare optics on the heat sink.

In general, the shape of the LED lighting device, in particular in plan view, is not limited. It is preferred that the LED lighting device has an elongated shape, in particular in the form of a bolt. In particular, the substrate carrying the LEDs, the diffuser optics and / or the anti-glare optics may have a band-like basic shape.

It is still an embodiment that the LED lighting device is a lamp, in particular a workstation lamp. However, the LED lighting device may e.g. also represent an LED module, in particular a part of a workplace lamp.

In particular, the LED lighting device may be a ceiling light or pendant light, or a part (e.g., an LED module) thereof.

The above-described characteristics, features, and advantages of this invention, as well as the manner in which they will be achieved, will become clearer and more clearly understood in connection with the following schematic description of exemplary embodiments which will be described in detail in conjunction with the drawings. In this case, the same or equivalent elements may be provided with the same reference numerals for clarity.

1 shows in a view obliquely from above an LED lighting device according to a first embodiment in an exploded view;

2 shows in a view obliquely from above the LED lighting device according to the first embodiment in an assembled state;

3 shows a sectional view of an end-side section of the LED lighting device according to the first embodiment in the assembled state;

4 shows the end-side section of the LED lighting device according to the first embodiment in the assembled state as a sectional side view;

5 shows in a view obliquely from above an LED lighting device according to a second embodiment in an exploded view; and

6 shows in a view obliquely from above a sectional view of an end-side section of the LED lighting device according to the second embodiment in an assembled state.

1 shows in a view obliquely from above an LED lighting device 11 according to a first embodiment in an exploded view. 2 shows an LED lighting device 11 in a view obliquely from above in an assembled state.

The LED lighting device 11 has several LEDs arranged in three rows R1, R2, R3 12 on that on a front 13 a substrate in the form of a band-shaped printed circuit board 14 are arranged. The light-emitting diodes 12 may be, for example, white light emitting diodes. Of the three rows R1-R3 are the LEDs 12 the two outer rows R1 and R3 arranged in parallel, while the light-emitting diodes 12 the middle row R2 parallel thereto, but offset by half an LED spacing.

With her back 15 is the circuit board 14 flat on a ribbon-shaped heat sink 16 in the form of a metal sheet, for example made of aluminum or copper, for example by means of a good heat-conducting adhesive tape or Wärmeleitklebers. As a result, an effective heat dissipation from the light emitting diodes 12 over the circuit board 14 on the heat sink 16 allows. The heat sink 16 especially like his of the circuit board 14 applied side have a cooling structure, eg cooling fins (o.Fig.).

On the circuit board 14 lies a translucent and light scattering diffuser optics 17 on. This has a band-shaped and plate-like basic shape, wherein they are above each of the light-emitting diodes 12 an upward bulge 18 having.

On the diffuser optics 17 is a glare-proofing look 19 applied, which has several light openings 20 having. The light transmission openings 20 are analogous to the LEDs 12 positioned and have a hexagonal shape in plan view. This results in the light transmission openings 20 a honeycomb pattern which is densely packed. The light transmission openings 20 So ensure a single glare of each arranged below LEDs 12 ,

3 shows a sectional view of an end-side section of the LED lighting device 11 , 4 shows the end-side section of the LED lighting device 11 as a sectional view in side view.

The heat sink 16 stands laterally over the circuit board 14 addition, and the glare-proofing 19 is edge and flush on the heat sink 16 attached, which also as the lid or bottom of the LED lighting device 11 can be viewed. The anti-glare look 19 presses on the diffuser optics 17 which the circuit board 14 on the heat sink 16 suppressed. As a result, a tight fit and a reduced heat transfer resistance can be achieved in a simple manner.

The light transmission openings 20 are designed as hollow reflectors and have as a reflector surface 21 straight sidewalls on. In a lower neck opening of the light openings 20 protrude the respective bulges 18 , The bulges 18 have a matching to the shape of the neck opening peripheral contour, here: a hexagonal peripheral contour. The anti-glare optics 19 facing upper surface is designed to faceted, with six side facets and a central facet.

When operating the LED lighting device 11 the LEDs shine 12 in the diffuser optics 17 , mainly in the area of the bulge 18 , This will be the light of the respective LED 12 generated light cone widened and homogenized. This reduces shading. Part of the bulge 18 passed light is directly through the associated light passage opening 20 blasted. Another, typically lesser, part hits the reflector surface 21 , Because the reflector surface 21 has straight side walls, the light incident on them is reflected for the most part obliquely to the main emission or symmetry axis S, whereby edge areas are more illuminated, which can further suppress shading.

A comparatively low (residual) light component of the diffuser optics 17 Incoming light is not directly or indirectly through the light passage opening 20 passed through, but for example to a page margin 22 guided, where it is uncoupled ineffective.

The LED lighting device 11 can be used as a work lamp or as a part of it.

5 shows in a view obliquely from above an LED lighting device 31 according to a second embodiment in an exploded view. 6 shows in a view obliquely from above a sectional view of an end-side section of the LED lighting device 31 in the assembled state.

The LED lighting device 31 is similar to the LED lighting device 11 built, with the LED lighting device 31 but now also an optical fiber 32 having, which up to a lateral edge 33 the LED lighting device 31 is guided. The light guide 32 closes at the side edge 33 flush with the anti-glare look 34 and the heat sink 16 from. The light guide 32 So it is between the glare control 34 and the heat sink 16 arranged and can in particular be pressed between them. The light guide 32 may for example consist of PMMA, ABS or another light-conducting plastic.

The light guide 32 surrounds the diffuser optics 17 circumscribes laterally and is in contact with it, leaving the side of the diffuser optics 17 leaking (residual) light into the light guide 32 coupled and from this to the side edge 33 is directed. There the light comes out and produces a lateral light, eg effect light.

Although the invention has been further illustrated and described in detail by the illustrated embodiments, the invention is not so limited and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

So can the light guide 32 and the diffuser optics 17 also be integrally formed as a extending to the side edge diffuser optics.

Also, instead of the individual light-emitting diodes 12 a plurality of light-emitting diodes in a group (cluster) may be arranged, for example, a group of three light-emitting diodes, which, for example, red, green and blue light and which a common primary mixed light optics is connected downstream.

Claims (12)

LED lighting device ( 11 ; 31 ), comprising - a plurality of light emitting diodes ( 12 ), - a glare control ( 19 ; 34 ), which the light-emitting diodes ( 12 ) at least in groups, in particular individually, blinding, and - one between the light-emitting diodes ( 12 ) and the anti-glare optics ( 19 ; 34 ) arranged diffuser optics ( 17 ). LED lighting device ( 11 ; 31 ) according to claim 1, wherein the anti-glare optics ( 19 ; 34 ) the light-emitting diodes ( 12 ) individually blended. LED lighting device ( 11 ; 31 ) according to one of the preceding claims, wherein the anti-glare optics ( 19 ; 34 ) a plurality of light passage openings ( 20 ), which in each case via an associated at least one light emitting diode ( 12 ) are arranged. LED lighting device ( 11 ; 31 ) according to claim 3, wherein the light transmission openings ( 20 ) as hollow reflectors for each associated at least one light emitting diode ( 12 ) are configured. LED lighting device ( 11 ; 31 ) according to one of the preceding claims, wherein the diffuser optics ( 17 ) a diffuser disc with above the at least one light emitting diode ( 12 ) arranged bulges ( 18 ). LED lighting device ( 11 ; 31 ) according to one of claims 3 or 4 in combination with claim 5, wherein the bulges ( 18 ) in an associated light passage opening ( 20 ) of the anti-glare optics ( 19 ; 34 ) protrude. LED lighting device ( 11 ; 31 ) according to one of the preceding claims, wherein - the light-emitting diodes ( 12 ) on a front side ( 13 ) of a common substrate ( 14 ) are applied, - a back ( 15 ) of the substrate ( 14 ) with a heat sink ( 16 ), - the diffuser optics ( 17 ) on the front side ( 13 ) of the substrate ( 14 ) and - the anti-glare optics ( 19 ; 34 ) on the heat sink ( 16 ) rests. LED lighting device ( 11 ; 31 ) according to claim 7, wherein - the heat sink ( 16 ) laterally across the substrate ( 14 ), - the anti-glare optics ( 19 ; 34 ) on at least one laterally projecting region of the heat sink ( 16 ) and - the anti-glare optics ( 19 ; 34 ) on the diffuser optics ( 17 ) presses. LED lighting device according to one of the preceding claims, wherein the diffuser optics ( 17 ) at least in sections to an outer side, in particular lateral edge ( 33 ), the LED lighting device is guided. LED lighting device ( 31 ) according to one of the preceding claims, wherein the LED lighting device ( 31 ) an at least partially up to an outer side, in particular lateral edge ( 33 ), the LED lighting device ( 31 ) guided light guide ( 32 ), which with the diffuser optics ( 17 ) is optically coupled. LED lighting device ( 31 ) according to claim 10, wherein the light guide ( 32 ) laterally, in particular laterally encircling, the diffuser optics ( 17 ) is arranged. LED lighting device ( 11 ; 31 ) according to one of the preceding claims, wherein the LED lighting device ( 11 ; 31 ) represents a workplace lamp or a part thereof.

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