DE4115187A1 - METHOD AND DEVICE FOR INFLUENCING THE ILLUMINATION STRENGTH AND COLOR TEMPERATURE OF LIGHT EMITTED IN A ROOM - Google Patents

Abstract

The invention concerns a process and a device for adjusting the illumination and colour temperature of a light produced by a fluorescent tube (12) and emitted in a room. Reflector elements (14) with lateral surfaces of different colours and different geometric shapes are disposed around the fluorescent tube (12). Each lateral surface reflects at a higher intensity in a given colour temperature range. Seasonal changes in natural light are simulated. This is achieved by placing the reflector elements (14) in various positions which are changed according to the time of day and the season.

Description

The invention relates to a method and a device for influencing the illuminance and color temperature by means of a fluorescent tube generated light and emitted into a room, with reflector elements that are arranged at least partially around the fluorescent tube, in each case parallel to the Axes extending along the longitudinal axis of the fluorescent tube are rotatable and side surfaces included, one of which is convex and red and reinforced in Color temperature range of 3600 ° Kelvin reflected, the other flat and is gold colored and is reflected in the color temperature range of 4500 ° Kelvin another is concave and silver colored and reinforced in the 5400 ° range Kelvin reflects.

A device of the type described above is known from EP-B-01 89 394. With this device, the color temperature and the illuminance of the the fluorescent tubes and the reflector elements outgoing light are changed. By adjusting the reflector elements to each other and the alignment of the differently reflecting side surfaces, it is possible to change the color temperature and the  Adapt illuminance to the course of daylight. The individual reflector elements can be controlled synchronously, if necessary by a preprogrammed control mechanism. The device is used instead of artificial Light sources with monotonous illuminance and color temperature are used.

The invention is based on the problem of the method described at the outset Influencing the color temperature and illuminance of the light in one To develop space in such a way that the light changes during a year different duration of solar radiation and angle of incidence Light conditions can be easily adjusted.

The problem is solved according to the invention in that the fluorescent tube Light spectrum emits that of that of sunlight on Earth on the day of Summer solstice around noon corresponds to that on spring and Beginning of autumn by means of the red side surfaces aligned with the fluorescent tube a red phase of thirty minutes in the morning and thirty minutes in the afternoon is generated and by means of the gold-colored side surfaces aligned on the fluorescent tube Gold phase of sixty minutes in the morning and sixty minutes in the afternoon is produced between the day of the winter solstice and the day of the summer solstice Red phases and the gold phases are each proportional to the number of past days starting from one and a half times the value of the beginning of spring to half the Value of the beginning of spring decreased and from the day of the summer solstice until on the day of the winter solstice again up to one and a half times the value of the The beginning of spring and autumn are increased and that outside of the red and Gold phases by means of the silver-colored aligned on the fluorescent tube Side surfaces a silver phase is generated.  

With this method, the color temperature can be generated by the fluorescent tube Light by utilizing the reflector elements of natural light on Be adjusted over the course of the year. Because of the influence of light on the human body, this adaptation to the natural conditions is special Cheap. The process can also be used in animal husbandry and in greenhouses will.

In a preferred embodiment, the illuminance of the in the room emitted light from the day of the winter solstice to the day of the Summer solstice proportional to the number of days from the winter solstice past days increased by thirty percent and thereafter from the day of Summer solstice by thirty percent by the day of the winter solstice reduced. With this method, the illuminance can be the natural Light course can be adjusted during the different seasons.

For the device, the object is achieved in that a Fluorescent tube is provided which corresponds to the light spectrum of the daylight spectrum corresponding to the summer solstice around noon on Earth generated and that as a drive for the reflector elements at least one stepper motor is provided, which is fed by a stepper motor controller with a Microprocessor is connected to which a clock and a read-only memory are connected are, in the data on the angular positions of the reflector elements for generation a red phase of thirty minutes in the morning and thirty minutes in the afternoon and one Gold phase of sixty minutes in the morning and sixty minutes in the spring and Beginning of autumn and to reduce the red and gold phase between the day of Winter solstice and the day of the summer solstice from one and a half times half of the values of the day of the beginning of spring or autumn and for the increase the red and gold phase between the day of the summer solstice and the day of the  Winter solstice from half to one and a half times the value of the days of the The beginning of spring or autumn and data on the angular positions for the generation of Silver phases are stored between the red and gold phases.

The use of stepper motors enables a very fine adjustment of the Reflector elements. By means of the clock, the times of day and the days in Annual cycle determined. The setting data of the reflector elements are fail-safe in the Read-only memory included.

The reflector elements are preferably arranged in an oscillating manner in the silver phase can be moved back and forth in the range of ± 30 °. The fluorescent tube is connected to a periodically reversed DC voltage. A very precise setting of the Angular position of the reflector elements is possible if the stepper motor rotates by 1.8 ° e.g. B. forty steps are required.

Another advantage should be noted. To the electrodes in fluorescent tubes To protect and to guarantee a longer service life, it is provided that after the Ignition of the tube the electrodes on both pins are connected to one to ensure even power distribution.

Further details, advantages and features of the invention do not only result from the claims, the features to be extracted from them - for themselves and / or in Combination - but also from the following description of in one Exemplary embodiments shown in the drawing.

Show it:

Fig. 1 is a device for influencing the color temperature and illumination intensity of emitted light in a space in a perspective view;

Fig. 2 is an enlarged view of the reflector assembly of FIG. 1,

Fig. 3 is a detailed view of a reflector element according to FIG. 2,

Fig. 4 is a block diagram of an arrangement for the adjustment of the reflector assembly of FIG. 1 to 3 and

Fig. 5 is a diagram of the course of brightness of the emitted light and the adjustment phases of the reflector elements as a function of the days of the year for influencing the daily and annual rhythm of brightness.

According to Fig. 1 is a surrounded by a reflector assembly (10) artificial light source is shown in the form of a fluorescent tube (12). The reflector arrangement ( 10 ) is located in a lamp housing ( 13 ), which can be attached to a ceiling or suspended from it, for example. The reflector arrangement (10) FIG mutandis. 2, at least from part of a ring around the fluorescent lamp (12), for example, on an imaginary cylinder surface or other curved surface reflector arranged elements (14) so as the coming of the fluorescent lamp (12) radiation to the desired extent to be able to modify and reflect in terms of color temperature and brightness. The reflector elements ( 14 ) - as is particularly illustrated in FIG. 3 - are formed by prismatic bodies which have bearing pins ( 16 ) or ( 18 ) at their ends, by means of which they can be mounted in the housing ( 13 ). Furthermore, friction pins, cable, gearwheels or the like can be arranged, for example, of the bearing journals ( 16 ) and / or ( 18 ), which interact with the adjacent reflector elements, in order, for example, to engage one end face of the housing ( 13 ) existing stepper motor ( 20 ) to allow a controlled and synchronous rotation of the reflector elements ( 14 ).

The reflector elements can be driven by a gear or direct drive. The reflector elements should be rotated at the same time, but in the opposite sense. Instead of a triangular reflector, for. B. also a square (1 × red, 2 × gold, 1 × silver) can be used. The red side of the reflector would be curved and matt on the surface, the golden sides would be flat and semi-matt and the silver side would be concave and high-gloss. The control of the individual reflector elements ( 14 ) can be preprogrammed so as to ensure alignment to the desired extent on the fluorescent lamp ( 12 ), which ultimately determines the illuminance and the color temperature of the emitted radiation.

Each reflector element ( 14 ) is a triangular prism or square prism with geometrically differently shaped side surfaces ( 22 ), ( 24 ) and ( 26 ). The different design of the side surfaces ( 22 ), ( 24 ), ( 26 ) should ensure, in addition to a different optical effectiveness to be described with respect to the incident radiation, that the radiation from the artificial light source in the form of the fluorescent lamp ( 12 ) is illuminating and / or color temperature can be varied.

Thus, the surface ( 22 ) is concave with respect to the fluorescent lamp ( 12 ), is preferably silver-colored by means of a special aluminum alloy such as, for example, a magnesium-aluminum alloy, and has optical properties which ensure that the illuminance increases and a color temperature of the radiation originating from the fluorescent lamp ( 12 ) is set to approximately 5400 ° Kelvin.

The side surface ( 24 ), on the other hand, is planar, although it also reflects UV radiation well, but to a lesser extent than the concave surface ( 22 ), and adjusts the color temperature of the emitted light to approximately 4500 ° Kelvin. The flat surface is also yellow and semi-glossy. These properties are preferably also achieved by a special aluminum alloy.

Finally, the third surface ( 26 ) is convex and increasingly reflects the red portion of the light coming from the fluorescent lamp ( 12 ), with a greatly reduced UV reflection taking place at the same time as the surface ( 24 ). Due to the convex shape, the reflected light component perceived by the surface ( 26 ) is the smallest compared to the reflection components of the other surfaces ( 22 ) and ( 24 ). Furthermore, the convex surface is red and matt, which also reduces the degree of reflection. It is increasingly reflected in the range of 3600 ° Kelvin.

The fluorescent tube ( 12 ) emits a light spectrum which is similar to that of sunlight on earth on the day of the summer solstice and whose wavelengths are between 290 and 770 nm.

The stepper motor ( 20 ), which is controlled by a stepper motor controller ( 28 ), is provided as the drive for the reflector arrangement ( 10 ). The inputs of the stepper motor control ( 28 ) are connected to outputs of a microprocessor ( 30 ) which is connected to a clock generator ( 32 ). Further inputs of the microprocessor are connected to an electronic clock ( 34 ) and to a read-only memory ( 36 ). The operating voltage for the microprocessor ( 30 ), the clock ( 34 ), the clock generator ( 32 ) and the read-only memory is generated by a rectifier bridge ( 38 ), the inputs of which are connected to the mains voltage.

Another rectifier bridge ( 40 ) generates the supply voltage for the fluorescent tube ( 12 ). The voltage of the rectifier bridge ( 40 ) is fed to the fluorescent tube ( 12 ) via a polarity reversal inverter ( 42 ). The polarity of the voltage at the connections of the fluorescent tube ( 12 ) is reversed every 20 minutes. The polarity reversal inverter ( 42 ) and a starter relay ( 44 ) for the fluorescent tube ( 12 ) are controlled by the microprocessor ( 30 ).

By aligning the individual reflector elements ( 14 ) on the fluorescent lamp ( 12 ), the emitted light is adapted to a desired course. The angular positions of the reflector elements ( 14 ) are set by means of the stepping motor ( 20 ). The reflector elements ( 14 ) are preferably arranged in an oscillating manner in the silver phase and can each be set to the desired angle between two angles, which are ± 30 °. A rotation of the stepper motor ( 20 ) z. B. 40 steps corresponds to a change in the angular position by 1.8 °.

The reflector elements ( 14 ) are set at the beginning of spring and autumn so that a red phase occurs in the morning of 20 minutes and in the afternoon of 20 minutes. Furthermore, by setting the reflector elements at the beginning of spring and autumn (25.3., 23.9.), A gold phase of 40 minutes in the morning and 40 minutes in the afternoon is set. Otherwise, the silver phase is set or used.

The duration of the red, gold and silver phases is changed depending on the calendar. In Fig. 5, the deviations of the red and gold phases from the values labeled 0 at the beginning of spring and autumn are shown in a diagram as a function of the seasonal trend. According to curve ( 46 ) of FIG. 5, the red and gold phases are 50% higher on the day of the winter solstice than at the beginning of spring or autumn and 50% lower on the day of the summer solstice (21.6.) Than at the beginning of spring or autumn . Between the day of the winter solstice and the day of the summer solstice, the red and gold phases fall linearly depending on the time interval from the day of the winter solstice. From the day of the summer solstice, the red and gold phases increase linearly depending on the time interval from the day of the summer solstice. The profile shown in Fig. 5 is afternoon in the afternoon based on the setting of the red phase of 20 minutes in the morning and 20 minutes to the spring and autumn and to start the setting of the gold phase of 40 minutes in the morning and 40 minutes for Spring and the beginning of autumn.

The illuminance is varied in the opposite sense. The illuminance at the beginning of spring and autumn the same and predetermined.

The illuminance, as can be seen from curve ( 48 ) in FIG. 5, is linear from the day of the winter solstice to the day of the summer solstice from -15% of the value at the beginning of spring to + 15% of the same value depending on the time interval to Winter solstice day increased. From the day of the summer solstice, the curve ( 48 ) falls until the day of the winter solstice.

By adjusting the red, gold and silver phases using the The reflector arrangement allows the color temperature and the illuminance of the light in the room over the course of a year in such a way that an alignment with the natural light takes place.

The values for setting the angular positions of the reflectors are available in the read-only memory ( 36 ) in addition to the program of the microprocessor ( 30 ). It is possible to save the angular positions as a table with reference to the calendar days. A space-saving option is to store some values of the angular positions, e.g. B. for the winter and summer solstice and the beginning of spring and autumn and to save the other setting data by linear interpolation from the stored data. The calendar days are determined using the clock ( 34 ).

The fluorescent tube ( 12 ) can be available on the market under the name True Lite, which emits a spectrum approximately corresponding to the natural spectrum of sunlight.

Claims (8)

1. A method for influencing the illuminance and color temperature of light generated by a light source such as a fluorescent tube and emitted into a room, wherein reflector elements which are at least partially arranged around the fluorescent tube are each rotatable about axes running parallel to the longitudinal axis of the fluorescent tube and contain side surfaces, one of which is convex and red and increasingly reflects in the temperature range of 3600 ° Kelvin, the other is flat and gold-colored and increasingly reflects in the range of 4500 ° Kelvin and another is concave and silver-colored and reinforced in the range of 5400 ° Kelvin reflected, characterized,
that the light source emits a light spectrum which corresponds to that of the sunlight on earth on the day of the summer solstice at noon,
that at the beginning of spring and autumn, a red phase of twenty minutes is created in the morning by means of the red side surfaces aligned with the light source and twenty minutes in the afternoon, and a gold phase of forty minutes in the morning and forty minutes in the afternoon is generated by means of the gold-colored side surfaces aligned on the fluorescent tube, that between On the day of the winter solstice and the day of the summer solstice, the red phases and the gold phases are each reduced in proportion to the number of days past from one and a half times the value of the beginning of spring to half the value of the beginning of spring and again from the day of the summer solstice to the day of the winter solstice be increased to one and a half times the value of the beginning of spring and autumn and that outside of the red and gold phases a silver phase is generated by means of the silver-colored side surfaces aligned with the fluorescent tube. 2. The method according to claim 1, characterized, that the illuminance of the light emitted into the room from the day of Winter solstice proportional to that until the day of the summer solstice Number of previous days increased by thirty percent and thereafter from Day of the summer solstice until the day of the winter solstice around same amount is reduced. 3.Device for influencing the illuminance and color temperature of light generated by means of a fluorescent tube and emitted into a room, wherein reflector elements which are at least partially arranged around the fluorescent tube are each rotatable about axes running parallel to the longitudinal axis of the fluorescent tube and contain side surfaces, of which one is convex and red and increasingly reflects in the temperature range of 3600 ° Kelvin, the other is flat and gold-colored and increasingly reflects in the temperature range of 4500 ° Kelvin and another is concave and silver-colored and increasingly reflects in the temperature range of 5400 ° Kelvin, characterized in that a fluorescent tube is provided which generates a spectrum corresponding to the light spectrum of the sunlight on the day of the summer solstice at noon on earth and that a stepping motor ( 14 ) drives the reflector element ( 14 ). 20 ) is provided which is fed by a stepper motor controller ( 28 ) which is connected to a microprocessor ( 30 ) to which a clock ( 34 ) and a read-only memory ( 36 ) are connected, in which data on the angular positions of the reflector elements ( 14 ) to produce the red phase of twenty minutes in the morning and twenty minutes in the afternoon and a gold phase of forty minutes in the morning and forty minutes in the beginning of spring and autumn and to reduce the red and gold phase between the day of the winter solstice and your day of the summer solstice from one and a half times Half of the value of the day of spring or autumn and to increase the red and gold phase between the day of the summer solstice and the day of the winter solstice from half to one and a half times the value of the day of spring or autumn and data on the angular positions are stored to generate the silver phase between the red and gold phases. 4. The device according to claim 3, characterized in that the reflector element ( 14 ) is arranged oscillating in the silver phase and can be moved back and forth in the angular range of ± 30 °. 5. Apparatus according to claim 3 or 4, characterized in that the fluorescent tube ( 12 ) is connected to a polarity reversal inverter ( 42 ) for polarity reversal of the polarity of the applied DC voltage. 6. The device according to one or more of claims 3 to 5, characterized in that each 1.8 ° rotation of the stepping motor ( 20 ) z. B is divided up to forty steps. 7. The device according to at least one of the preceding claims, characterized, that a stabilizer is connected, which is preferably via a photodiode or resistance to the drop in lumen due to aging of the light source compensates. 8. The device according to at least one of the preceding claims, characterized, that a controller according to the seasonal rhythm according to that of Microprocessor coming information the light source lumens regulates.