DE102014104339A1 - Central brightening element for LED lights - Google Patents

Abstract

The invention relates to a luminaire having a multiplicity of LED light sources which are arranged in a plane opposite a light exit surface of the luminaire, and having an optically effective translucent cover arranged in the light exit surface, wherein the LEDs are mounted on a plurality of individual circuit boards and electrically contacted, which are arranged in the plane, wherein a central portion of the plane remains free of LEDs and a reflector element extending from the plane towards the light exit surface is provided in the central portion defining one or more circumferential reflector surfaces extending from the plane in FIG Direction to the light exit surface are inclined towards each other.

Description

The invention relates to luminaires which have as light sources a multiplicity of LEDs (light emitting diodes, which also include organic light emitting diodes).

The lights mentioned above are often constructed so that a large number of LED light sources emit their light from behind on an optically effective, translucent cover of the lamp and the light is deflected by the optical properties of the cover before the lamp on the front of the Cover, which faces the LEDs, leaves. Viewed from the outside, only the optically effective translucent covers are visible on which the LEDs in the interior of the luminaire can be seen only schematically as light intensity differences.

In order to produce the most homogeneous possible intensity distribution on the light exit surface of the cover, is in the art usually a uniform, z. B. provided orthogonal arrangement of LEDs in the lamp. For lamp sizes that z. B. for recessed luminaires with pitches of 600 mm × 600 mm or at 625 mm × 625 mm are common, such a construction, however, is relatively expensive, because the LEDs are arranged on a very large board. Such boards are not only expensive to manufacture, but also bulky during assembly, so that the cost and risk of damage when replacing boards is correspondingly high.

Object of the present invention is to provide an aforementioned LED light, which is easy to use and allows cost-effective production.

The object is achieved by a luminaire having a multiplicity of LED light sources which are arranged in a plane opposite a light exit surface of the luminaire, and having an optically effective, transparent cover arranged in the light exit surface,
wherein the LEDs are mounted on and electrically contacted on a plurality of individual boards arranged in the plane, a central portion of the plane remaining free of LEDs, and a reflector element extending out of the plane towards the light exit surface being provided in the central section, which defines one or more circumferential reflector surfaces which are inclined towards each other from the plane towards the light exit surface.

In order to save printed circuit board material or to improve handling for mounting and removing boards in the luminaire, it is provided according to the present invention to attach a plurality of individual boards behind the optically active optically transparent cover and to contact them electrically, wherein a central portion in the level of the LEDs remains free. This central section would be visible as a shadow through the optically effective, translucent cover from the outside. To compensate for this optical flaw, a special reflector element is provided in the central portion. The reflector element has one or more reflector surfaces, which are inclined relative to the plane of the LEDs so that the light of the LEDs is deflected so that the impression of a homogeneous light intensity distribution is awakened from the outside in supervision of the translucent cover on the surface to be illuminated. It is also advantageous that the reflector element can be easily placed in the central portion of the boards of the LEDs or on an underlying structure. In contrast to a construction which z. B. reflector elements has at the outer edges of the board at the transition to the edge of the lamp housing, the reflector element of the present invention can construct with much less highly reflective material. Furthermore, the assembly is easier because the boards occupied with LEDs need not be fitted between the sensitive edges provided with highly reflective material.

The reflector element according to embodiments of the present invention may take various forms with one or more reflector surfaces. According to one embodiment, the reflector element comprises a conical or frusto-conical reflector surface. According to an alternative embodiment, a plurality of reflector surfaces are provided, which are placed in the form of a pyramid or a truncated pyramid. The pyramid may have a regular or irregular footprint with three, four, five, six or more corners. The base of the reflector element, ie a circle in a conical element or a polygon in a pyramidal element, may be adapted to a regular structure of the arrangement of the LEDs within the plane. For an orthogonal arrangement of LEDs, in particular a pyramid-shaped reflector element with a square base surface offers itself, because in this way the impression is created from the outside in a view of the translucent cover that a regular pattern of the LEDs continues steadily over the reflector element. The LEDs can be arranged on the boards in a regular pattern and the regular arrangement of the LEDs can continue across multiple boards or across all boards away. A reflector element with a different shape, eg. B. cone-shaped, but this impression can also arise, because it should be considered that by the optically effective, translucent cover the underlying LEDs are anyway only dimly to recognize.

According to a preferred embodiment with a reflector element having a base with several corners, one side of the base can be aligned parallel to an axis of symmetry of the regular LED array. This reinforces the described effect that the LED array appears to continue regularly in the area of the central portion. According to an alternative embodiment, which is particularly preferred when LEDs of different light color find application, the side of the base can also against an axis of symmetry of the regular LED array in an angle different from 0 °, z. B. between 10 ° and 30 ° aligned. In the case of a regular LED arrangement of LEDs of different color, the effect can arise that the predominantly reflected light radiation from the reflector element mainly consists only of the light of the LEDs of a light color. However, if the reflector element is arranged at an angle relative to the regular arrangement of the LEDs of two colors, the break in symmetry eliminates the effect that only predominantly light of a light color, namely the light of the LEDs which are arranged closest to the reflector element, is reflected. As a result of the break in symmetry, light of differently colored LEDs impinges on the reflector surfaces in different intensities, so that the impression of a homogeneous light distribution of the two light colors, that is to say the optically effective translucent cover. H. the mixed color, also in the area of the central section arises.

According to a preferred embodiment, the reflector surface or the reflector surfaces define or define a degree or a curvature in one or more sections which respectively contain the axis of the longitudinal extent of the reflector element in the direction of the light exit surface and / or parallel to the plane of the LEDs. In particular, a concave curvature is preferred. Due to the nature of the curvature, a bundling or widening of the reflective light radiation can be generated. Depending on the arrangement of the LEDs in the vicinity of the reflector element, a widening or bundling of the reflected light may serve to enhance the impression of a uniform light distribution of the central portion.

According to a preferred embodiment, the LEDs, which are arranged in a plane, are bounded by a square or a rectangle. These embodiments can be used, in particular, for ceiling luminaires which are attached to square installation dimensions, e.g. B. 600 mm × 600 mm or 625 mm × 625 mm, are also advantageous. Although the LEDs are arranged in a square, the boards on which the LEDs are arranged may be rectangular in this embodiment, in particular four rectangular boards are provided, each with one of its longer side and one of its shorter side together one side of the square. With this embodiment, by four smaller boards and the reflector element, the square area over which light of the lamp to be submitted to fill.

In a preferred embodiment, the LEDs except for a central area are arranged in an orthogonal grid over the plurality of boards. This embodiment is particularly preferred for luminaires with a square format.

According to some embodiments, of the plurality of LEDs, LEDs may also be included in at least two different colors. As described above in particular in connection with the reflector element which is oriented at an angle relative to the axis of symmetry of the regular LED array, in one embodiment with two different light colors, the impression of a uniformly luminous area in the area of the central section can be generated via the reflector element. Such embodiments are preferred if the light of the luminaire is to be produced by the mixture of two LED types of different color. Furthermore, it is also possible for the LEDs of the different colors to be controlled independently of one another, so that different light colors can be generated with the luminaire, wherein the total light color is always set by the mixture of the LEDs of different color.

According to one embodiment, the boards have a full-surface shape. Such boards are advantageous when relatively small board sizes can be selected. According to an alternative embodiment, however, it may also be provided that cutouts are provided in the circuit boards in order to save on board material. In particular, the boards may be in the form of joined lines or strips. For example, the boards may be comb-shaped to z. B. to produce an orthogonal pattern for the LED array. It can also mesh two comb-shaped boards in each case. This embodiment is advantageous, for example, for applications with two different LED colors, because then in each case a group of LEDs with a light color can be arranged on a circuit board.

According to preferred embodiments, all or at least some boards are each formed in the same shape. This simplifies the production. It can z. B. of four boards each two be the same.

It is further contemplated that, according to one embodiment, adjacent uniform blanks each are arranged rotated through 90 ° with respect to each other. For example, can be filled in this way by four rectangular or comb-shaped boards and with the reflector element in the central portion of the shape of a square. Likewise, a rectangle can be filled by several boards. The boards can each be arranged at the same distance from each other. However, the distances can also z. B. to ± 30% vary.

According to a preferred embodiment, the optically active, translucent cover is designed to be light-scattering. For this purpose, one or both surfaces of the cover can be frosted. It is also possible to provide light-diffusing elements (eg, a diffuser disk or foil) in a cover disk to form a light-diffusing cover. These embodiments are preferred when a uniform possible light output should be made.

Instead of or in addition to the light-scattering cover may also be provided on the cover, a refractive structure. The refractive structure may in particular comprise lens or prism elements on one of the surfaces of the cover. This embodiment is particularly suitable when the optically active, translucent cover glare the lamp to be generated. For example, the combination of a translucent cover having light diffusing and refractive structures may include a transparent cover having the refractive structures on the outside and / or inside of the cover, and an additional light diffusing film or disk may be inserted on the inside of the cover. Preferably, an air gap is provided between the light-diffusing structure and the refractive structure because it improves the efficiency of refraction of light by the refractive structure.

Other features and advantages of the present invention will become apparent in connection with the following description of preferred embodiments, which will be described in conjunction with the accompanying drawings. The following is shown in the figures.

1 FIG. 12 is a schematic plan view of a first embodiment of a luminaire of the invention without an optically effective translucent cover. FIG.

2 represents a sectional drawing through the lamp according to 1 with cover.

3 - 9 show different embodiments of the reflector element respectively in a side view (left) in a plan view (center) and in a perspective view (right).

10 shows a plan view of a lamp in one embodiment.

11 shows a plan view of a lamp of another embodiment, which has LEDs with two different colors.

Referring to the 1 and 2 is schematically a plan view and a sectional view of a first embodiment of the lamp according to the present invention to see. The lamp has a square cross-section, through the open side of a box-shaped housing 2 is predetermined. The defined light exit surface is, as in the 2 represented by an optically effective, translucent cover 4 closed. In the embodiment according to 2 is the translucent cover 4 formed by a lens. The disc has a frosted surface so that the light impinging on the disc is evenly scattered.

Inside the case 2 are on multiple boards 6 each a number of LEDs 8th arranged. Like in the 1 shown in the supervision are four boards 6 each having an orthogonal array of LEDs in the housing 2 intended. In each case adjacent boards 6 are rotated by 90 ° to each other. A shorter and a longer side of two boards 6 together form one side of the square, within which the LEDs 8th are arranged regularly.

By the arrangement of four rectangular boards 6 a central area remains free in the middle. The central area is covered by a reflector element 10 filled.

According to the embodiment in the 1 and 2 includes the reflector element 10 four reflector surfaces, which are joined together in the manner of a pyramid with a regular square base. As in the sectional view 2 As can be seen, the pyramid extends to the top of the plane of the LEDs towards the light exit surface of the luminaire. The inclination of the reflector surfaces of the reflector element 10 is chosen so that the light of the LEDs, which is located near the reflector surfaces, Partially deflected at the reflector surfaces, so that the impression of a continuous continuation of the otherwise orthogonal arrangement of the LEDs arises. Because of the optically effective translucent cover 4 the direct view of the LEDs from the outside is not possible anyway, the viewer takes the LEDs through the optical cover only dimly true. The viewer can tell the difference between the regular LED arrangement and the game image of the LEDs 8th in the reflector element 10 barely noticeable in the central section from the outside. It should be noted that the 1 the lamp without optical translucent cover 4 represents. Through the cover 4 In the operation of the luminaire is the arrangement of the separate LED boards 6 , the LEDs 8th and the reflector element 10 not visible in the central section.

In the 3 to 9 are different embodiments of the reflector element 10 shown. The various embodiments of the reflector elements 10 may be made of sheet metal or of a plastic, for example. The reflector surfaces can be made high-gloss, reflective or matt.

In the simple embodiment of the 3 the reflector element comprises a conical surface. This conical surface is in principle suitable for many different LED arrangements. In particular, in LED arrangements with a star-shaped structure is suitable as a cone element. However, even for orthogonal grid cone elements can be used, because the difference to a pyramid with square base through the transparent cover 4 barely perceptible.

The 4 and 5 show reflector elements in the form of pyramids with triangular or square regular base. These reflector elements are particularly suitable, for example, for tetragonal or hexagonal arrangements of LEDs.

The 6 shows an example of a reflector element, which is formed in the manner of a pyramid with concave curved reflector surfaces. The curvature extends in each case in a horizontal sectional plane. This arrangement provides for a bundling of the reflected light. In addition or instead, a curvature can be provided in a vertical sectional planes.

7 shows a pyramidal arrangement of flat reflecting surfaces, similar to the reflector element 10 in the 1 and 2 , However, the tip of the pyramid is cut off, resulting in a truncated pyramidal arrangement. Since the tip of the pyramid for the reflection of the regular orthogonal LED array is anyway optically ineffective, the truncated pyramid according to 7 replace a pyramid with a tip in its lighting effect.

The 8th and 9 show embodiments of the reflector element according to the 6 and 7 However, at the base side fasteners in the form of tongues or edges are provided. The reflector element according to 9 can be attached to the tongues (eg made of metal for bending) on a bottom side of the reflector housing. The edges of the reflector element according to 8th can on the bottom side of the housing z. B. be attached by screws or rivets. It is also possible, the reflector element together with one or more boards 6 in the case 2 to fix.

The 10 shows a plan view of a further embodiment according to the present invention, wherein the optically effective translucent cover is not shown to allow the insight into the lamp. The LEDs are, except for the central portion, in which the reflector element 10 is arranged arranged in an orthogonal grid. Unlike the embodiment according to 1 have the boards 6 However, no rectangular shape, but are formed of strip-shaped boards, which form the shape of a comb. This can be compared to full-surface, rectangular boards, as in the 1 represented, board material can be saved. It can also be seen that the shape of the boards 6 is sufficient to form a closed regular orthogonal grid of LEDs.

11 shows a variant of the embodiment according to 10 , In this embodiment, LEDs are 8th and 8th' provided in two different colors. The LEDs 8th the first light color are on boards 6 arranged as in the embodiment according to 10 shown. The LEDs 8th' the second light color are on boards 6 ' arranged, which are also comb-shaped. Two boards each 6 and 6 ' interlock and form a rectangular structure. Four of the intermeshing board pairs are arranged in a ring shape rotated by 90 °. The overall structure of the LED array is thus formed by two orthogonal gratings, wherein the grids are arranged offset at an angle of 45 ° to each other. A special feature of this embodiment is the arrangement of the reflector element. Would you like the reflector element as in the 10 arrange arranged, there is the problem that light of the LEDs 8th the first light color would be reflected more strongly than the light from the LEDs 8th' in the second color, because due to the LED arrangement LEDs 8th the first light color closer to the reflector element 10 lie as LEDs 8th' the second light color. To compensate for this effect is the reflector element 10 with a base side at an angle to the major axes of the orthogonal grid of the LEDs 8th . 8th' arranged. The angle is 15 °, but may vary between 10 ° and 30 ° for different embodiments. In conjunction with the curved reflector surfaces of this embodiment and the arrangement of 15 ° with respect to the major axes of the orthogonal grid, the light becomes the light color of the LEDs 8th' , which are further away from the pyramidal surfaces, more reflected, so that in the result no different brightness impression between the two light colors of the LEDs 8th respectively. 8th' arises, although the LEDs 8th lie closer to the reflector element. Exemplary are a light path of an LED 8th and two light paths of two LEDs 8th' in the 11 located. It can be seen that the LED 8th although closer to the reflector element 10 However, the light of the LED is reflected in an area that causes less light bundling. The light of the LEDs 8th' In contrast, the concave curved region of the reflector surface is also reflected, so that a bundling arises, which causes the greater impression of brightness.

As related to the 1 has been described, the optically effective translucent cover may comprise a diffusion element in the form of a diffuser disk or diffuser sheet. According to further embodiments, which are not shown in the figures, however, a refractive structuring may be provided in particular below the diffuser element. In particular, the cover on the outside of prism structures, conical or pyramidal structures or lens structures of refractive material (preferably are PU or PMMA) include. These light-refracting structures can, in particular, for glare-freeing the luminaire by directing the light. Preferably, the combination of a diffuser element on the inside and a refractive structure on the outside is provided. In this case, an air gap between the diffuser element and the element which carries the refractive structure is provided. The light gap has the effect of breaking the light from the optically thinner to the denser medium at the interface with the element provided with refractive structures after it has exited the diffuser element. This increases the effectiveness of the refractive structure. In a simple embodiment, however, it can also be provided that a cover on the inside has a matted surface for light control and on the outside has refractive structures for directing the light.

The above-described embodiments may be modified in various ways without departing from the subject matter of the invention, which is defined by the appended claims. In particular, the invention is not limited to the illustrated orthogonal LED arrays, but a variety of regular arrangements may be provided. Furthermore, the LED array is not limited to a square arrangement. In particular, rectangular or round shapes for the arrangement of the LEDs in the plane of the luminaire can also be selected. Also, the embodiment with two different light colors is not strictly limited to two types of LEDs. It is also possible to provide three or more differently colored LEDs within the luminaire. Furthermore, it may be provided that each or each of the LEDs is assigned a lens body (in particular arranged directly above it), which generates a widening of the light distribution of the LED, in order to achieve a homogenization of the light when hitting the optically effective cover. It should be noted, however, that the embodiment of the invention relates to lights, not to LED display screens. According to the embodiments of the invention, the light should be emitted as evenly as possible from the optically effective transparent cover, while display screens serve to produce a high-contrast light output for generating the image.

LIST OF REFERENCE NUMBERS

2

casing

4

optically effective, translucent cover

6, 6 '

circuit board

8, 8 '

LED

10

reflector element

Claims (15)

Luminaire with a variety of LED light sources ( 8th ), which are arranged in a plane opposite to a light exit surface of the luminaire, and with an optically effective translucent cover arranged in the light exit surface ( 4 ), the LEDs ( 8th ) are mounted and electrically contacted on a plurality of individual boards, which are arranged in the plane, wherein a central portion of the plane is free of LEDs ( 8th ) remains and a reflector element extending from the plane in the direction of the light exit surface ( 10 ) is provided in the central portion defining one or more circumferential reflector surfaces inclined towards each other from the plane towards the light exit surface. Luminaire according to claim 1, wherein the reflector element ( 10 ) comprises a conical or frusto-conical reflector surface. Luminaire according to claim 1, wherein the reflector element ( 10 ) comprises pyramid-shaped or truncated pyramid-shaped reflector surfaces, wherein the pyramid or the truncated pyramid comprises a regular or irregular base surface with three, four, five, six or more corners. Luminaire according to claim 3, wherein one side of the base is parallel or at a non-zero angle, e.g. B. between 10 ° and 30 °, is aligned with respect to an axis of symmetry of the regular LED array. Luminaire according to one of the preceding claims, wherein the reflector surface or surfaces of the reflector element ( 18 ) in one or more sections, which the axis of the longitudinal extension of the reflector element ( 10 ) in the direction of the light exit surface or parallel to the plane of the LEDs ( 8th ), a straight line or a curvature, in particular a concave curvature define. Luminaire according to one of the preceding claims, wherein the plane in which the LEDs ( 8th ), are bounded by a square or a rectangle. Luminaire according to one of the preceding claims, wherein the boards ( 6 ) are rectangular and in particular, with reference back to claim 6, a longer and a shorter side of two adjacent rectangular boards together form one side of the square. Device according to one of the preceding claims, wherein the LEDs ( 8th ) except for the central area in an orthogonal grid over the multiple boards ( 6 ) are arranged. Luminaire according to one of the preceding claims, wherein the plurality of LEDs LEDs ( 8th . 8th' ) has at least two different colors. Luminaire according to one of the preceding claims, wherein at least some of the boards ( 6 ) have a full-surface shape. Luminaire according to one of the preceding claims, wherein at least some of the boards ( 6 . 6 ' ) Have cutouts, in particular of joined lines, z. B. comb-shaped, are formed. Luminaire according to one of the preceding claims, wherein all or at least some boards ( 6 ) have the same shape. Luminaire according to claim 12, wherein adjacent uniform boards ( 6 ) are arranged rotated by 90 ° to each other. Luminaire according to one of the preceding claims, wherein the optically effective translucent cover ( 4 ) is light-scattering, in particular has a matted surface. Luminaire according to one of the preceding claims, wherein the optically effective translucent cover ( 4 ) has a refractive structure, in particular lenses or prism elements on a surface.

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