DE3526590A1 - Method and arrangement for controlling an illumination system - Google Patents

Abstract

In the case of an illumination system (4), in a room (1) to which daylight has access, disturbances resulting from the different colour temperatures of the daylight (3) and of the artificial illumination (5) are avoided in that the colour temperature of the daylight is measured and the colour temperature of the artificial illumination is followed up in a corresponding manner, for example by switching light sources (8, 9, 10) of different colour temperature on or off or by opposingly brightening or dimming such light sources, it being possible to keep the overall illumination intensity constant, or by using light sources having a controllable colour temperature. <IMAGE>

Description

Method and arrangement for controlling a lighting Appendices g e __

The invention relates to a method for controlling a lighting system in a room accessible to daylight, and an arrangement for carrying out the method with at least one light source, a lighting measuring device and a control device controlled by this, the at least one operating parameter of the light source (n) controls as a function of the lighting measurement values.

It is already known to control the brightness of a lighting system as a function of the daylight brightness, for example to switch on artificial lighting when the daylight brightness, or that of a photometer Measured daylight illuminance falls below a specified threshold value and, vice versa, is switched off again, as soon as there is sufficient daylight again. In doing so, however, the color or color temperature was taken into account the lighting and daylight were not taken into account.

In addition, it has been customary in many places in the past to have larger rooms, e.g. open-plan offices, shops, Shopping centers and factory halls, to be lit purely artificially, with daylight being switched off. Included so became the color temperature of artificial lighting chosen as they are considered beneficial or suitable for the people working there or for the purpose in question became. A possibility of change or adaptation the color temperature was not intended.

It soon became apparent, however, that such permanent artificial lighting of interiors was enormous and inefficient energy consumption, especially when the illuminance is at the recommended level higher values, e.g. 1000 lux, has been raised. Since all light sources used for interior lighting, especially incandescent lamps, but also low-pressure fluorescent lamps, Also called fluorescent lamps by some manufacturers, only a small part of the supplied ones To convert energy into usable light, the remaining, excess energy has to be used in such systems as generally unused waste heat from an expensive, oversized air conditioning system be eliminated, especially in summer temperatures.

Therefore, even in modern business and industrial buildings the knowledge prevailed Mixed lighting for reasons of economy and energy saving to be provided for interior lighting using as much daylight as possible, as is the case with Private rooms is common anyway. Because of the usually different color temperatures of the artificial Lighting and daylight, however, such mixed lighting is often seen as an unpleasant twilight felt that causes disturbing color shifts and colored shadows. Everywhere where the color recognition or -assessment plays a role, e.g. in graphic companies or textile companies, is such lighting only usable to a very limited extent or not at all.

To eliminate the mentioned disadvantages of the prior art, the present invention has the task of to create a method and an arrangement for controlling a lighting system with which color disturbances due to the different color temperatures of the artificial and daylight lighting used at the same time avoided or eliminated.

In the case of the method according to the invention, this task becomes solved by measuring the color temperature of the daylight and the color temperature of the light of the lighting system is regulated depending on the measured color temperature of the daylight.

The arrangement according to the invention is characterized in that that the lighting measuring device as a color temperature measuring device designed and arranged in such a way that it matches the color temperature of the daylight outside able to measure, and that the control device is designed, the color temperature of the lighting system depending on the measured values of the color temperature measuring device to control.

The color temperature control of the lighting system can be controlled electrically by means of light sources Coloring temperature can be achieved, e.g. by using of lamps with controllable color temperature »or with pre-installed color filters or filters with controllable color temperature .

The light sources can, however, also have several lamps with different chi edlicher / 'aufwei sen, which step by step depending on measured color temperature of daylight can be switched on or off, or those with suitable Light / dark controls are regulated in the opposite direction.

Another lighting measuring device can advantageously be used within the room be provided that measures the color temperature of the overall lighting and the color temperature Light source (s) automatically readjusts to the color temperature of daylight. At the same time, the Illuminance in the room is regulated to a specified value and with sufficient daylight brightness the artificial lighting can be switched off. If there is no daylight, a fixed color temperature can be set.

The invention is explained on the basis of the exemplary embodiments shown in the figures. Show it:

Figure 1 shows a room with a lighting system and lighting measuring devices,

Figure 2 shows a control scheme for a lighting system,

FIG. 3 a first light source with a variable color temperature,

Figure 4 shows another light source with variable color temperature and

FIG. 5 shows a light source with a filter with controllable color temperature.

FIG. 1 shows a room 1 which receives daylight 3 through a window. A lighting system k is provided on the ceiling, which additionally supplies the interior of the room with artificial light 5. On the outside of the Raura near the window 2, or also inside the room, but facing away from the lighting system k and not irradiated by this, a lighting measuring device 6 is arranged, which is designed as a color temperature measuring device of a known type and which measures the color temperature of the incident daylight in the simplest way In this case, this can consist of a red and a blue-sensitive photosensor in a quotient circuit, the quotient of the sensor signals being a measure of the color temperature. The measured color temperature will usually be around 6000 K in direct sunlight, but can rise to around 12000 K in a cloudless blue sky. In contrast, the color temperatures of commercially available artificial light sources are between around 3000 K for incandescent lamps and around 6000 K for daylight fluorescent lamps.

In order to avoid the difficulties and disruptions when using mixed lighting consisting of daylight 3 and artificial light in room 1, the lighting system k is designed to be controllable in terms of its color temperature. The measured values of the color temperature measuring device 6 are processed via a control device 7, which in turn controls the color temperature of the artificial lighting so that it is more or less matched to the color temperature of daylight.

In a simplest embodiment, the lighting system h has at least two, expediently also several light sources 8, 9-10 with different, graduated color temperatures, for example one warm-tone, white-light and daylight fluorescent lamp each. The control device then has a plurality of threshold value switches which form a plurality of color temperature ranges and, depending on the measured color temperature of the daylight, switch on one of the lamps with the corresponding color temperature. However, a larger number of lamps can be provided and several lamps can be switched on in each stage, whereby a finer gradation can be achieved, and in addition the total number of switched on light sources can thus be better matched to the available daylight by only always changing that number is operated by light sources that are required to achieve a given illuminance inside the room.

Instead of stepwise, the color temperature control of the lighting system h can also take place continuously, for example by having at least two light sources with very different color temperatures, such as a warm tone and a daylight fluorescent lamp or corresponding incandescent lamps, and the control device 7 heat / dark controls

for the two light sources with opposite control direction, as in the " Control scheme shown. At a low color temperature T " of the daylight is practically only the yellow warm-tone lamp G switched on, with increasing color temperature the blue daylight lamp B is switched on more and more, while the yellow lamp is turned down, and at a high color temperature T "is practically only the blue one Lamp B in operation. In this way, the color temperature of the artificial lighting 5 can be continuous adapt to that of daylight 3.

In principle, the control can only be carried out using the measuring device 6, since the properties of the light sources used and their dependence on operating parameters are known, so that a suitable program for the control device can be specified without difficulty, and the design of the control device 7 for certain Light sources does not pose any significant problems. However, in order to become independent of the light sources used, it is advantageous to provide a further lighting measuring device 11 at a representative location in the room 1. This can be set up to measure the color temperature of the entire lighting inside the room and to readjust the color temperature of the lighting system h via the control device 7 until the color temperature corresponds to the day measured by the measuring device 6. At the same time, the additional measuring device 11 can be set up to measure the illuminance at the measurement location and to regulate the brightness of the light sources via the control device 11 so that it is always constant. In this way it is achieved that even with mixed lighting, regardless of the daylight intensity, both a uniform color temperature of the lighting prevails and an assigned overall illuminance is maintained.

Instead of using several light sources with different ones Color temperature, however, the invention can also be carried out with light sources whose color temperature itself is changeable and controllable.

Figure 3 shows such a light source, which is used as a luminous

k 2.
material lamp is formed with layers Ί3> ~ 4G running in the longitudinal direction of the lamp and lying next to one another in the circumferential direction and made of different phosphors. These phosphors are chosen so that they emit light with different color temperatures when excited by UV, for example with graduated color temperatures between 400 and 10,000 K. The lamp or its sockets are rotatably mounted in the lamp around the lamp axis. The control device controls this rotation of the lamp around its axis via a motor in such a way that, depending on the color temperature of the daylight, a corresponding fluorescent strip of the lamp comes to rest and emits light of the desired color temperature through the lamp cover lens.

Instead, as FIG. H shows, instead of a rotatable lamp, a permanently mounted lamp with a movable filter with color permeability that changes in the direction of movement can be provided. When the filter moves, parts of different colors come in front of the lamp so that the effective color temperature can be controlled.

Finally, as shown in Figure 5, before a permanently mounted lamp 20, a color filter 21 with electrically controllable permeability can also be provided. With the metered and controllable absorption of a suitable spectral component, the Control and regulate the color temperature of the transmitted light as required.

ORIGINAL ΐ

The use of such electrochromatic filters has the advantage that no mechanically moved, fault-prone, one Parts subject to wear are used as the control of the color or the spectral transmittance takes place purely electrically. The disadvantage of a certain loss of light through a filter can be eliminated by that instead of using light sources whose color or spectral distribution can be controlled electrically directly. Suitable light sources of this type are, for example, discharge tubes with at least two ionizable gases that have a different discharge spectrum and by different Types of current can be excited to a gas discharge. Also metal halide lamps with at least two different ones. Metals with different evaporation temperatures can be useful if the coldest part of the lamp envelope can be brought to different temperatures by electrical heating or cooling, so that at the different Temperatures Metal vapors with different compositions and correspondingly different ranges, i.e. of different colors are present in the gas discharge space. Also electroluminescent light sources with electrically controllable Color or other suitable light sources can be used.

The described method according to the invention is advantageous Can be used wherever exact color reproduction and color recognition are important. However, the inventive Arrangement can also be used with particular advantage in living spaces to improve lighting comfort and thus living comfort to improve and increase.

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L ο ο r s e i t e

Claims (1)

Claims Method for controlling a lighting system in a room accessible to daylight, characterized in that the color temperature of the daylight is measured and the color temperature of the light of the lighting system is regulated as a function of the measured color temperature of the daylight. 2. The method of claim 1, characterized g ekennzeichnet that the color temperature of the light of the illumination system is at least approximately adjusted to the color temperature of sunlight. 3. A method according to claim 2, characterized ekennzeichnet g, that additionally, the color temperature of the overall illumination * is measured within the space, and the color temperature of the lighting system is controlled so) of the light, that the color temperature of the overall illumination corresponds to the color temperature of sunlight. k. Method characterized ekennzeichnet according to any one of claims 1-3 »g, that additionally the daylight brightness is measured, and the illumination system is only switched on if the daylight brightness is below a predetermined threshold. 5. The method of any of claims 1-31 characterized ekennzeichnet g, in addition that the illumination intensity measured within the space, and the brightness of the illumination system is controlled so that the measured illuminance is a predetermined value. 6. Arrangement for carrying out the method according to one of claims 1-5 with at least one light source (4, 8, 9 »10), a lighting measuring device (6) and a control device (7) controlled by this, the at least one operating parameter of the light source ^) controls depending on the lighting measurement values, characterized in that the lighting measuring device (6) is designed as a color temperature measuring device and is arranged so that it is able to measure the color temperature of the daylight (3) in the outside space, and that the control device (7 ) is designed to control the color temperature of the light (5) of the lighting system (k) as a function of the measured values of the color temperature measuring device (6). In that the illumination system (4) 7 · arrangement according to claim 6, characterized ekennzeichnet g at least two light sources (8 "9" 1O) with different color temperature, and that the control device (7) has a threshold circuit which, depending on the color temperature range in which the measured color temperature of the daylight is, switches different light sources (8, 9 »IO) with the corresponding color temperature on or off. 8. The arrangement according to claim 6, characterized in that the lighting system (h) has at least two light sources (G, Β) with different color temperatures, and that the control circuit (7) light / dark controls with opposite control direction for the two light sources (G , Β), which control the brightness of the light sources (G, B) in their relationship to one another so that the resulting color temperature of the light sources (G, Β) corresponds at least approximately to the measured color temperature of daylight. 9. An arrangement according to claim 6, characterized g ekennzeichnet that the lighting system (k) a light source (12-21) with controllable Färbtemperatur. 10. The arrangement according to claim 9 » characterized in that the light source has a lamp (12) with several radiation areas (13-16 ) with different color temperatures and radiation directions, which can be oriented by moving the lamp so that they are in the room ( i) Emit light (5) with the corresponding color temperature. 11. The arrangement according to claim 10, characterized in that the radiation areas (13-16 ) have different phosphors with different color temperatures. 12. An arrangement according to claim 9 »characterized ekennzeichnet g, that the light source (18, I9) comprises one of a lamp (18) prefixed filter (19) having locally different color permeability, by its movement, the color temperature can be varied relative to the lamp (18). 13. An arrangement according to claim 9 »characterized ekennzeichnet g, that the light source (20, 21) comprises one of a lamp (20) vorgestztes filter (21) with electrically controllable color permeability. 14. Arrangement according to one of claims 6 - I3, dadvirch g ekmarks that inside the room (l) a further measuring device (11) is provided which measures the color temperature of the lighting and via the control device (7) to the measured color temperature of the Daylight 15 · arrangement according to claim 14, characterized ekennzeichnet g, that the measuring device (11) additionally controls the illuminance in the room to a predetermined Vert.