AT16164U1 - Lighting arrangement with color variable light output - Google Patents

Abstract

The invention relates to a lighting arrangement (100) for room or object lighting, the lighting arrangement (100) having a light source (10) and first optical means (15, 115) for spatially spectral splitting of the light emitted by the light source (10) second optical means (20, 120) disposed in the optical path of the light split by the first optical means (15, 115) and adapted to selectively suppress portions of the light, and third optical means (25, 125 ) for superimposing the light influenced by the second optical means (20, 120).

Description

description

LIGHTING ARRANGEMENT WITH COLOR-DIFFICULT LIGHTING

The present invention relates to a lighting arrangement which is adapted to output light having a desired spectral composition. Furthermore, the invention relates to a method for operating a corresponding illumination arrangement.

The spectral composition of the light emitted by a light light plays an essential role in lighting technology. It is known, for example, that the spectral composition of light has an influence on the biorhythms of people who are in a room illuminated with artificial light. In particular, for example, an increased short-wave, that is to say blue portion of the light has a stimulating effect, whereas light with a lower color temperature, that is to say a so-called warm shade, has a rather soothing function. In addition to these effects, the spectral composition of light also plays a role in the lighting of objects or products in shops. These appear only for observers in the correct colors or shades, if contained in the light spectral components match the surface properties of the object to be illuminated. Often referred to in this context is the so-called Color Rendering Index (CRI), which provides information on the extent to which a light is suitable for illuminating an object in such a way that it actually appears in the correct hues. Finally, it is also known that, for example, particularly short-wave components of the light influence the surfaces of objects illuminated with it, for example, they can be damaged in the case of illumination over a relatively long period of time.

In the past, the possibilities of making color changes or adjustments to the color of the light emitted by a lamp were limited to essentially two basic techniques.

On the one hand, special, prefabricated color filters were used, which were arranged downstream of the actual light sources of the lights and filter out certain spectral components of the light emitted by a light source. An adjustment of the spectral composition of the light finally emitted by the light can then be made in this case only by a corresponding replacement of the filter.

A second possibility for color change is to use several different colored light sources, which can be controlled individually and the light is emitted together as a mixed light through the lamp. By correspondingly individually controlling the individual light sources, for example in the colors red, green and blue, it is then possible to set almost any color locus in the so-called color space spanned by the light sources used.

However, both known solutions still bring limitations in terms of the possibilities for adjusting the spectral composition of the light emitted by a lamp with it.

Thus, the former variant is obviously limited to the use of special color filters that need to be replaced manually to make changes. This is not only associated with a relatively high outlay, but restricts from the outset the possibilities for using desired spectral compositions, since not as many color filters are available or when using several filters at the same time there is a risk that too high a proportion of the total light is suppressed by the filters.

In the case of the variable mixing of different light components, it is in principle possible to set a desired color location within the abovementioned color space, but this does not mean that the specified light then ultimately has a desired spectral composition. Instead, the color locus results from the combination of the discrete wavelengths determined by the individual light sources, so that the light finally emitted has exclusively spectral components based on these individual light sources. By contrast, wavelength ranges which lie outside the individual wavelengths of the light sources are not part of the light which can be achieved in this case. As a result, with the aid of this second solution, as a rule, only a relatively low color rendering index can be achieved.

The present invention is therefore based on the object to provide a novel possibility for the realization of a lamp available, in which there are many possibilities for adjusting the spectral composition of the light emitted by the lamp.

The object is achieved by a lighting arrangement having the features of claim 1. Advantageous developments of the invention are the subject of the dependent claims.

The inventive solution allows the creation of almost any spectra or spectral compositions, which in contrast to the above-mentioned, known from the prior art solutions variable spectra with high accuracy and without the manual change of filter or light sources can be achieved. In addition, the solution according to the invention is characterized by a relatively low complexity, since in particular the use of a plurality of different light sources can be dispensed with. Instead, only a single light source or a plurality of similar light sources can be used, which simplifies the structure of the arrangement as a whole.

According to the invention it is provided that the illumination arrangement comprises a light source whose light is spectrally shaped before leaving the illumination arrangement. For this purpose, first optical means are provided which cause a spatial spectral splitting of the light emitted by the light source. With the aid of further optical means, which are arranged in the beam path of the light split by the first optical means, optionally subregions of the split light can then be blanked out or reduced in order to achieve a total of a spectral composition of the light in the desired manner. With the help of third optical means finally the light thus obtained is again summarized or superimposed so that it is delivered as a combined beam for lighting purposes. This light then has the desired spectral composition and intensity.

[0013] According to the invention, therefore, an illumination arrangement is proposed, which has: a light source, first optical means for spatially spectral splitting of the light emitted by the light source, second optical means, which are arranged in the beam path of the light source [0017] third optical means for superimposing the light influenced by the second optical means on the light source, which are split by the first optical means and configured to selectively block out or reduce portions of the light.

Further, a method for generating light for the room or object lighting is proposed, comprising the following steps: a) generating light by means of a light source, b) spatially spectral splitting of the light emitted by the light source, C) hiding or reducing portions of the spatially spectrally split light, d) superimposing the light influenced in step c) to a homogeneous beam for the light output.

Ultimately, therefore, the arrangement of the three optical means mentioned above is used to spectrally form the originally emitted by the light source light in almost any manner. Since in this procedure, of course, no new wavelength components can be added to the light initially emitted by the light source, but rather selectively suppressed or reduced in intensity, it is preferably provided that the originally emitted light of the light source comprises the largest possible wavelength range , That is, ideally, a so-called white light source is used. However, this does not necessarily have to be the case. If, for example, only light with wavelengths within a certain range is to be emitted with the aid of the illumination arrangement, this can already be taken into account in the selection of the original light source and a light source can be selected which does not necessarily cover all wavelength ranges of the visible light.

According to a first variant of the invention it is provided that the first optical means cause a splitting of the light by refraction. In this case, it may then be provided, in particular, that the first optical means comprise a prism which spatially splits the light of the light source in such a way that beams of different wavelengths merging into one another are obtained in a known manner.

In the same way, however, according to a second variant, a splitting of the light could also be achieved by diffraction. In this case, it may be provided, for example, that the first optical means comprise a grid.

The third optical means are preferably formed complementary to the first optical means, whereby the structure of the lighting arrangement is simplified as a whole and can be made compact.

There are also different possibilities for the spectral shaping of the light spatially split by the first optical means. A first embodiment provides that an LCD arrangement is used. The different colors of the spatially split light thereby fall on different individually controllable areas of the LCD arrangement, in which case the corresponding light can be selectively passed through or reduced or completely suppressed by corresponding activation of these individual areas. Alternatively to the use of an LCD arrangement, the second optical means may also comprise a so-called micromirror array, as is known, for example, from devices for the projection of optical information, such as, for example, beamers or the like. In this case, therefore, ideally, matrix-like micromirrors are provided which can be controlled individually in order to either redirect the incident light in a desired direction or to direct it out of the beam path, so that it is no longer used for the further light emission. In this case, therefore, the light is either completely reflected or decoupled in the direction of the light output, in which case targeted influencing of specific wavelengths is achieved by having a plurality of individual mirrors of the micromirror array responsible for a particular wavelength and selecting the correspondingly adjusted mirrors associated color proportion of the light is affected.

The control of the second optical means is preferably carried out via a control unit, wherein it can be provided in particular that in the context of a control additionally a sensor is provided which provides information on the basis of which then the control of the second optical means. In this case, it can be provided that the sensor is aligned with an object to be illuminated, with the light originally emitted by the light source additionally being able to be detected and evaluated. It can then be made to the effect that a lit object appears particularly well in the desired color, so there is a high quality color rendering.

Finally, therefore, proposed by the inventive solution, a novel lighting treatment arrangement for the illumination of rooms and / or objects, in which compared to previously known solutions can be taken much more flexible and easy influence on the spectral composition of the light.

The invention will be explained in more detail with reference to the accompanying drawings. FIG. 1 shows a first exemplary embodiment of a lighting arrangement according to the invention; FIG. 2 shows a second embodiment of a lighting arrangement according to the invention; Figure 3 shows a variant for the spectral shaping of the spatially spectrally split light with the aid of a micromirror array; Figures 4 and 5 possible approaches to control the illumination arrangement according to the invention in the context of a scheme and Figure 6 shows an advantageous embodiment when using a sensor for evaluating the output from the light source light.

Figure 1 shows a first embodiment of a lighting arrangement according to the invention, which, as already mentioned, is provided for room lighting or for the illumination of objects. A conceivable field of application would be, for example, the use in museums for the targeted illumination of certain objects, since here often the objects - eg. Pictures or sculptures - should or should be illuminated specifically with light of a certain spectral composition. The reason for this may be, on the one hand, that the object only appears in the right way to an observer if the light incident thereon is matched in terms of its spectral composition to the surface properties of the object. Furthermore, it is known that certain wavelengths may well have damaging effects on illuminated objects and, for example, can lead to damage to the surface or the like. Also in this case, it may be desired that the light is adapted in a special way with the aid of the present invention. Further, since a particular advantage of the lighting arrangement according to the invention is that with their help, a very high color rendering index can be achieved, the use in photo studios or the like would be conceivable.

Other advantageous applications for the lighting arrangement according to the invention are shops or shops in which objects should be specifically highlighted or presented by a specific lighting. The same applies to the application in architecture.

Finally, as already mentioned, the spectral composition of the light also influences the well-being of persons, which is why another useful field of application of the present invention is the use in hospitals and / or wellness areas of hotels.

Thus, FIG. 1 shows the essential components of the illumination arrangement according to the invention, which, for example, can be used in a ceiling light or a spotlight. Shown are only the components for light generation according to the procedure of the invention, while on the other hand has been dispensed with the representation of the other components of the lamp or the spotlight. Finally, the illumination arrangement according to the invention forms a light source, which can usually be used in a luminaire, but whose light can be adjusted in almost any desired manner with respect to its spectral composition.

The first essential component of the lighting arrangement according to the invention, generally designated by the reference numeral 100, is accordingly a primary light source 10 which outputs a first beam I. As already mentioned above, the inventive spectral shaping of the finally emitted light of the illumination arrangement 100 is based on the idea of deliberately suppressing or reducing individual wavelength ranges of the light emitted by the primary light source 10. This inevitably means that the light of the primary light source 10 determines the framework conditions for the finally emitted light. Accordingly, in order to be as flexible as possible in this point, the light source 10 should emit light, which covers as far as possible all wavelength ranges of the visible spectrum. Ideally, therefore, a so-called. White light source is used, under certain circumstances also light sources could be used, which already have certain limitations in terms of the spectral composition of the light from the outset, if this is irrelevant to the subsequent light output.

The emitted from the primary light source 10 beam I is then first converted to a directly associated with the light source 10 primary optics 11 in a parallel beam II, whereby the subsequent spectral shaping is simplified. This beam II then falls first on the first optical means, which are responsible for the aforementioned spectral spatial splitting of the light and output a beam III.

In the illustrated embodiment, the spectral spatial splitting of the light is achieved by refraction, which is why the first optical means are realized by a prism 15 in the present case. The mode of operation of such a prism 15 is known per se and is based on the fact that different wavelengths are refracted, ie deflected, so that the previously existing homogeneous color beam II is split or expanded into a beam III, which in principle consists of a plurality consists of juxtaposed individual beam bundles, which, however, then each have an individual wavelength or color.

With the help of another, the prism 15 downstream lens 16 of this spectrally expanded beam III is then influenced such that the individual partial beams with the corresponding colors parallel to each other in the optical axis. This "parallelization" simplifies the subsequent spectral shaping of the light, but if necessary, the lens 16 could also be dispensed with.

The split light is then affected by means of second optical means 20 as desired to adjust the spectral composition of the light. In the illustrated embodiment, an LCD arrangement 20 is used for this purpose, which consists of a plurality of individually controllable segment 21. In a known manner, these individual segments 21 can be controlled in such a way that their transparency is changed, that is to say that incident light is in principle passed unhindered or is attenuated or completely blocked. Shown in the present embodiment is a case in which a single segment 21 is driven in such a way that the partial beam impinging thereon is completely blocked. As can be seen, all further light is transmitted substantially unhindered, so that the beam IV leaving the LCD array 20 consists of the same wavelength portions as the light emitted by the primary light source 10, but the wavelength portion passing through the corresponding LCD segment has been blocked, has been hidden.

The further optical elements are then formed substantially complementary to the optical elements which are responsible for the spatial spectral splitting. That is, in the beam path of the LCD assembly 20 downstream of another lens 22 is provided, which is ideally identical to the lens 16 and the beam IV in a complementary manner to the lens 16 to another prism 25 aligns. This second prism 25 then represents the third optical means and combines the light into a final homogeneous and collimated beam V having the composition affected by the LCD assembly 20. This light is then used by the illumination arrangement 100 for emitting light and, if appropriate, can be influenced in the desired manner with the aid of further optics - not shown - in order to be used for illumination purposes. However, these further optical elements are then used exclusively to determine the light emission characteristic of the luminaire with regard to the light distribution, however, a further influencing of the spectral composition of the light is not provided.

From the above description, it can be seen that with the aid of the arrangement 100, it is possible to influence the spectral composition of the light in a relatively simple manner. It is only necessary to drive the individual elements 21 of the LCD assembly 20 in a suitable manner. The higher the resolution of the LCD arrangement 20, the finer the influence on the spectral composition of the light can be taken, however, even at a relatively low resolution compared to previously known solutions, a significantly better possibility for adjusting the spectral composition of the light consists.

It should be noted that the principle of spectral shaping is already known in principle, but so far exclusively for laboratory purposes - for example, to provide light for analysis purposes with a certain composition - was used, but not to realize a light source for general lighting tasks.

An advantage of the solution according to the invention is also that apart from the LCD arrangement in all other components of the illumination arrangement 100 according to the invention is relatively robust elements. The risk that the operation is adversely affected by external influences, so is relatively low. In addition, the arrangement according to the invention is also characterized by a relatively simple structure, which allows the design of very compact lighting arrangements.

Figure 2 shows an alternative possibility for the realization of a lighting arrangement according to the invention, in which case comparable elements have been provided with comparable reference numerals.

The main difference compared to the embodiment of Figure 1 is that here the spectral spatial splitting of the light emitted from the primary light source 10 light is not by refraction, but by diffraction. For this purpose, the lens 11 is arranged downstream of a grating 115, which in turn splits the incident, homogeneous beam II in a manner consisting of different wavelength ranges bundle III in a known manner. The spectral shaping of the light split in this way then takes place in turn with the aid of an LCD arrangement 20, ie in the same way as in the embodiment in FIG. 1. The combination of the light influenced thereby takes place again in a complementary manner to the splitting, ie with the aid of a second grating 125, which corresponds in terms of its function to the second prism 25 of the embodiment of Figure 1.

Of course, in principle, it would also be conceivable to use a grating for splitting the light and then to combine the spectrally influenced light with the aid of a prism (or to use grids and prisms in the reverse order), but ideally the means for spectral splitting as well as designed to combine or superimpose the light complementary, whereby the structure of the lighting arrangement according to the invention is further simplified.

In the embodiments of Figures 1 and 2, the spectral shaping of the light was carried out with the aid of the above-mentioned LCD assembly 20. Figure 3 now shows an alternative possibility, both in the use of prisms and in the use of gratings could be used for the spectral splitting of the light.

Instead of the LCD assembly 20 - the other elements of the arrangement correspond to those of Figure 1 or 2 - a micromirror array 120 is provided in this case, which consists in a known manner by a preferably matrix-like arrangement controllable individual mirror 121. As can be seen in FIG. 3, these mirrors 121 can usually assume two different positions, wherein in a first position the incident light is reflected in such a way that it is emitted in one direction, via which a light output of the illumination arrangement then takes place. In a second position, however, in the

Mirror 121τ is present, the light is reflected in an opposite direction and deflected so that it is not discharged. In other words, depending on the position of the mirrors 121, the light of the respective individual beam which impinges on the mirror 121 is either forwarded or coupled out for the purpose of light emission, which in turn makes it possible to influence specific wavelength ranges in a targeted manner.

The control of the means for spectral shaping of the light, that is, for example, the LCD array 20 or the micromirror array 120 is preferably carried out with the aid of a corresponding control unit. In this case, it is possible, in particular, to carry out an automation or regulation by using a sensor, which performs an adaptation of the light in such a way that optimum illumination conditions are present.

A first possibility for the application of the principle is shown in FIG. 4, wherein in this case additionally a sensor 50 is used, which is directed directly onto the object 200 to be illuminated. That is, with the aid of the sensor 50, which makes a spectral measurement, it is determined in which colors the object 200 illuminated by the illumination arrangement actually appears. This information is provided to the control unit 40, which performs a control of the spectral shaper 20 or 120 in a corresponding manner. If the control unit 40 determines how the illuminated object 200 should appear, a desired illumination can be achieved in a very simple way in the course of a regulation in this way.

A further development of the concept according to FIG. 4 is shown in FIG. 5, with the aid of the sensor 50 additionally detecting and evaluating the light emitted by the light source 10 and split spectrally. As a result, additional information is available on the basis of which a further optimized activation of the LCD arrangement 20 or of the micromirror array 120 can be carried out. In this case, the grating 115 illustrated in FIG. 2 is used in a particularly advantageous manner for splitting the light, since - as shown in FIG. 6 - it is possible to evaluate the split light in a very simple manner. Namely, since a grating diffracts the light in a known manner so that diffraction patterns of different so-called orders are formed, it is preferably provided that the 0-order light, which is the largest component of the light, be forwarded to the spectral shaping and used for the light emission. By contrast, the more strongly deflected light of the first order, which would scarcely be usable anyway for the light emission, is directed to the sensor 50, which in the present case is formed by a CMOS chip. This ideally has a comparable resolution as, for example, the LCD arrangement used for spectral shaping, so that the light can be evaluated in a simple manner and a control can be carried out based thereon.

Ultimately, therefore, allows the solution of the invention in a very simple manner, spectrally influence light so that it can be used flexibly and varied for lighting purposes.

Claims (10)

claims 1. A lighting arrangement (100) for room or object lighting, characterized in that the illumination arrangement (100) comprises: • a light source (10), • first optical means (15, 115) for spatially spectral splitting of the light source (10 ), second optical means (20, 120), which are arranged in the beam path of the light split by the first optical means (15, 115) and designed to selectively hide or reduce partial regions of the light, third optical means (25, 125) for superposing the light influenced by the second optical means (20, 120). 2. A lighting arrangement according to claim 1, characterized in that the first optical means (15, 115) cause a splitting of the light by refraction, wherein the first optical means (15, 115) in particular comprise a prism; and / or that the first optical means (15, 115) cause a splitting of the light by diffraction, wherein the first optical means (15, 115) comprise in particular a grating. 3. Illumination arrangement according to one of the preceding claims, characterized in that the third optical means (25, 125) complementary to the first optical means (15, 115) are formed. 4. Lighting arrangement according to one of the preceding claims, characterized in that the second optical means (20, 120) comprise an LCD arrangement; and or 5. Lighting arrangement according to one of the preceding claims, characterized in that it has a control unit (40) for controlling the second optical means (20, 120). 6. Lighting arrangement according to one of the preceding claims, characterized in that it further comprises a sensor (50) which is directed to one of the illumination assembly (100) illuminated area, wherein the driving of the second optical means (20, 120) based on the information provided by the sensor (50) takes place. 7. Illumination arrangement according to claim 6, characterized in that the sensor (50) or another sensor detects the light emitted by the light source (10), spectrally split light. 8. A method for generating light for the room or object lighting, characterized in that the method comprises the following steps: a) generating light by means of a light source (10), b) spatially spectral splitting of the light emitted from the light source (10) , c) hiding or reducing partial areas of the spatially spectrally split light, d) superimposing the light influenced in step c) into a homogeneous beam for the light emission. 9. The method according to claim 8, characterized in that the spatial spectral splitting of the light emitted by the light source (10) by refraction, in particular by means of a prism; and / or that the spatial spectral splitting of the light emitted by the light source (10) by means of diffraction, in particular by means of a grating takes place. 10. The method according to claim 8 or 9, characterized in that a light-illuminated area or an object illuminated with the light observed and based on the fading or reducing partial areas of the spatially spectrally split light is made. For this 6 sheets of drawings