BE1020514A3 - LIGHT CONTROL SYSTEM, LIGHT CONTROL SYSTEM NETWORK OR METHOD FOR OPERATING THE LIGHT CONTROL SYSTEM OR THE LIGHT CONTROL SYSTEM NETWORK. - Google Patents

Description

Light control system, light control system network or method for operating the light control system or the light control system network.

This invention relates to a light control system according to the preamble of the first claim.

The present invention also relates to a light control system network and a method for operating the light control system or the light control system network.

For example, WO2011135524 describes a light dome for diffusing daylight into a building as described in the preamble of the first claim. The light dome described by WO2011135524 comprises a daylight diffusing device for installation in a roof opening of the building and a mirror device. The mirror device is rotatably mounted above the daylight diffuser and provided for reflecting light to the daylight diffuser. The mirror device further comprises a mirror, a motor for rotating the mirror device and a control for controlling the motor. The control is such that the mirror device is brought to an optimum position in which as much light as possible is reflected to the daylight diffusing device. The control comprises a measuring device arranged for measuring the light intensity of light incident on the mirror. The measuring device is provided with a first and a second light sensor and a shadow element arranged for creating a shadow on the first or second light sensor, and a processing unit for processing the light intensity measured by the light sensors. The control is provided for determining an adjusted optimum position of the light intensity measured by the first and the second light sensor.

Although such a skylight allows more light to be distributed optimally in the building, it was found that in some situations insufficient light is available in the building at certain locations, for example because there is insufficient light available to be reflected by the mirror device to the daylight diffuser, for example, because the sun is partially shielded by clouds and / or has already partially or completely disappeared below the horizon, for example at night.

In such situations it was necessary to switch on the artificial light source present in order to obtain sufficient light at the locations. Such control of the artificial light source, however, requires a manual intervention that requires someone to switch on the artificial light source, which takes time and is often inaccurate so that the light source is often switched on too early or switched off too late or even switches off the light source. is becoming. In addition, energy, often electricity, is unnecessarily used to power the artificial light source.

It is therefore an object of the present invention to provide a light control system according to the preamble of the first claim wherein an improved control of the artificial light source is achieved.

This object is achieved according to the invention with a light control system which has all the features of the first claim.

To this end, the processing unit is provided for converting the light intensity measured by the light sensors to an expected illuminance at a predetermined location in the building and correspondingly controlling the artificial light source in order to obtain a predetermined illuminance at the predetermined location.

It has been found that such control of the artificial light source allows obtaining a predetermined illuminance at the predetermined location in the building without requiring manual intervention so that a more accurate switching on and off of the artificial light source is achieved.

Although light control systems are already known in which artificial light sources are operated in dependence on a measured light intensity of light, additional light sensors must always be provided in such light control systems. For example, US 6,340,864 B1 describes a light control system in which a light sensor is provided at a location in order to control an artificial light source in dependence on measured light at the location. In such a system, however, an additional light sensor must always be mounted, which is often undesirable since such a light source takes place, can be inadvertently covered by objects and / or persons, often requires energy, etc.

It was found that with the present invention, the first and the second light sensor on the one hand allow the mirror device to be controlled in such a way that a more optimum position of the mirror device is obtained and such more light is reflected to the daylight diffusing device and on the other hand the light intensity measured by the first and the second light sensor can be used to determine the expected illuminance at a predetermined location without having to place additional light sensors. Thus, without the use of additional light sensors, an improved lighting can be obtained at the predetermined location since a predetermined illuminance is always obtained without unnecessary use of the artificial light source and as much use as possible of the naturally available light outside the building. In addition, it was found that by controlling the artificial light source in such a way, the control of the artificial light source is less dependent on the specific situation in the building, such as, for example, location, color, dimensions, shape, etc. of furniture, floors, walls, etc.

According to preferred embodiments of the present invention, the processing unit is provided to determine an illuminance on the light sensors based on the light intensity measured by the light sensors and to determine the expected illuminance at the predetermined location in the building on the basis of the illuminance determined on the light sensors. Such a configuration makes it possible to determine the expected illuminance in a sufficiently accurate manner at the predetermined location in the building.

The adjusted optimum position is determined from a difference between the light intensity measured by the first sensor relative to the one measured by the second sensor. This difference in light intensity is caused by the shadow of the shadow element, which falls on the first / second sensor when the position of the mirror device is not optimal.

In addition, the measuring device and control according to the invention ensure that the optimum position is searched for and maintained on the basis of current measurements of the light intensity incident on the two sensors, which is a measure of the light intensity incident on the mirror. In this way, an incorrect position of the mirror device, which according to the state of the art can be caused by an error in the time and / or the position on the earth's surface, can be avoided according to the invention, while the control remains simple. Furthermore, in this way an optimum orientation of the mirror device during the day can also be obtained, taking into account local obstacles or elements that create shadow, such as for example an antenna box next to the dome, high-rise buildings in the neighborhood, difference in slope on one and the same roof , etc.

According to preferred embodiments of the present invention, the light sensors are located above the ceiling of the predetermined location. Such a configuration has the advantage that the sensors remain easily accessible via the daylight-spreading device, preferably via the roof of the building. Cabling is also avoided in the building and the sensors are more independent of the specific situation in the building, for example placement of furniture, colors of walls, etc. In addition, such mounted sensors are less visible, which is perceived as more aesthetic by spectators. The sensors also remain more out of reach of people in the building, which reduces the risk of damage, voluntary or voluntary covering, etc.

According to preferred embodiments of the present invention, the light control system comprises at least two light domes and the processing unit comprises a central processing unit and a local respective processing unit for each of the respective light domes, the local processing units being connected to the central processing unit and the central processing unit being connected to the artificial light source, wherein the respective local processing units are provided for processing the light intensities measured by the respective light sensors in the respective light domes and the central processing unit is provided to transmit the respective light intensities processed by the local processing units to the central processing unit. artificial light source. Such a configuration allows the local processing units to be provided to provide the driver with an adjusted optimum position of the mirror device and the central processing unit is provided to control the artificial light source to provide more optimum illumination of the predetermined location. Although the connection between the central processing unit and the local processing unit can for instance take place via an electrical signal over an electrically conductive wire and the connection thereto comprises a physical communication network, for instance via a physical computer network, the connection can also be established by means of a wireless communication network and the connection thereto comprises a wireless communication network. A wireless communication network has the advantage that no physical network has to be provided and that remote light domes can also be included in the light control system.

According to preferred embodiments of the present invention, the light control system comprises at least two artificial light sources. In such a configuration, the control of the artificial light sources is considerably simplified compared to the previous manual control of the artificial light sources, since especially with a plurality of artificial light sources, the control of the artificial light sources becomes more complicated and thus the risk of unnecessary energy consumption for driving the artificial light sources increases.

According to preferred embodiments of the present invention, the artificial light source is a lamp such as, for example, a tube lamp, an incandescent lamp, etc.

According to preferred embodiments of the present invention, the artificial light source is an electrically driven artificial light source such as, for example, a tube lamp, an incandescent lamp, etc.

According to preferred embodiments of the present invention, the processing unit is provided on the basis of the light intensity measured by the first and the second light sensor and the period of time that the artificial light source is driven to determine the amount of energy that is saved compared to a continuous control of the artificial light source. Based on the determined amount of energy that is saved compared to a continuous control of the artificial light source, the performance of the light control system can be determined and / or monitored. In addition, it becomes possible for a user of the light control system to charge a fee based on the determined energy saved, making it possible, for example, for an installer of the light control system to charge a user of the light control system an amount for the use of the light control system based on the amount of energy saved by the user that would normally have been used by the artificial light source or sources.

According to preferred embodiments of the present invention, the light control system comprises an interface where a user of the light control system can consult one or more of the following: the amount of energy saved compared to a continuous control of the artificial light source, the drive of the artificial light source , the light intensity measured by the first and / or second sensor, the illuminance determined by the processing unit, for example the central processing unit and / or local processing units, the illuminance determined at the predetermined location, the measured output of the daylight diffusing device, the position of the mirror device , the voltage on the battery, etc. Optionally, such an interface can also allow you to enter certain parameters of the light control system such as, for example, one or more of the following parameters: the predetermined illumination intensity, the height at which the he mirror device is placed above the floor of the predetermined location, the number of windows around the predetermined location, etc.

According to preferred embodiments according to the invention, the control is provided with means for determining a zero position, for example an electronic compass or reed contact (s) for determining a zero position, preferably directed substantially to the east, such that the position of the mirror device at sunrise is almost optimal.

According to preferred embodiments according to the invention, the control is provided for looking up an initial; optimum position during a complete revolution of the mirror device. The initially optimum position can be looked up by performing a complete revolution of the mirror device and determining at which orientation the measured light intensity is highest. This embodiment can serve as an alternative to the means for determining a zero position, for example the electronic compass or the reed contact (s), or as a supplement to this.

According to preferred embodiments of the present invention, the control is provided to determine the adjusted optimum position when a comparison value calculated on the basis of the light intensities measured by the first and the second light sensor, respectively, exceeds a predetermined limit and for periodically determining the comparison value. Such a control makes it possible to determine when it is necessary to look up a more optimum position by using the existing light sensors.

According to further preferred embodiments of the present invention, the comparison value is equal to the absolute value of a value based on a difference (d) of light intensities measured by the first and the second light sensor respectively divided by a value based on a sum (s) of the light intensities measured by the first and the second light sensor, for example \ d / s \. Such an absolute value appears to be a good benchmark for determining when a more optimum position should be looked up. It has been found that the predetermined limit is preferably 0.01 and preferably only the adjusted optimum position is determined if the comparison value is greater than 0.01, i.e. for example \ d / s \> 0.01, since a good positioning with such a value can be achieved, but excessive repositioning, with associated energy consumption, is avoided.

According to preferred embodiments of the present invention, the control is provided to determine the adjusted optimum position by turning the mirror device on the basis of a reference value calculated on the basis of the light intensities measured by the first and the second light sensor, respectively. Such a reference value makes it possible to determine the adjusted optimum position by using the values of the light sensors themselves.

The reference value is further preferably equal to a quotient of a value based on a difference of light intensities measured by the first and the second light sensor respectively and a value based on a sum of light intensities measured by the first and the second light sensor respectively. It was found that a good adjusted optimum position can be obtained on the basis of such a reference value.

Preferably, based on the reference value, the mirror device is rotated clockwise if the reference value is greater than 0 and rotated counterclockwise if the reference value is less than 0.

Preferably, as long as the comparison value exceeds the predetermined limit, the control is provided for controlling the motor so that the mirror device rotates according to the reference value until the comparison value does not exceed the predetermined limit. For example, a cycle is run through the control as long as the comparison value is greater than the predetermined limit, preferably 0.01. During each step of the cycle, the mirror device is rotated according to the reference value by the motor driven by the driver, preferably for a predetermined time or during a predetermined angle. For example, if the comparison value becomes smaller than the predetermined limit after such a turning of the mirror device, the cycle stops.

The values based on a difference of light intensities measured by the first and the second light sensor, respectively, are preferably determined by taking an average of at least two differences of at least two pairs of light intensities measured by the first and the second light sensor, respectively, at different times. The values based on a sum of light intensities measured by the first and the second light sensor, respectively, are preferably determined by taking an average of at least two sums of light intensities measured by the first and the second light sensor, respectively, at different times. The same corresponding measured light intensities are used for the sum and the difference. .

For example, some light intensities measured substantially simultaneously by the first and second light sensors are stored in order to calculate these average values. Preferably at least 2, but more preferably 5, values of the first and the second light sensor respectively are measured at the same moments and stored in order to calculate a corresponding time, preferably 5 times, a sum and a difference, the difference the light intensity measured by the first light sensor is always minus the light intensity measured by the second light sensor, after which the average of the sums and the differences is calculated, so that an average of the sums, preferably 5, is obtained and an average of the differences, preferably 5. On this basis, the reference value and the comparison value are determined, the comparison value being the absolute value of the reference value.

In embodiments of the present invention, control is provided as long as the comparison value exceeds the predetermined limit to replace at least one of the at least two pairs of values measured by the first and the second light sensor with a pair of values measured by the first and the second sensor after or while turning the mirror device. Preferably, the control is provided to replace the at least one, preferably periodically, stored values measured by the first and the second light sensor with values measured by the first and the second sensor after or during the cycle, rotating the mirror device in order to adjust the comparison value to the adjusted position of the mirror device so that it can be checked whether the mirror device must continue to rotate in order to assume an optimum position. To this end, the oldest of the stored values are preferably replaced by the last measured values. For example, at the end of each cycle, new values are measured and stored that replace the oldest stored values until then.

According to preferred embodiments according to the invention, the control is provided for periodically looking up the adjusted optimum position. More preferably, the period for looking up the adjusted optimum position is less than 10 minutes, such as, for example, 5 minutes. This makes it possible to save energy as a modified position is not constantly sought out.

The drive is furthermore preferably provided for looking up the adjusted optimum position after an extended period if the measured light intensities are insufficiently different from each other in function of the time. It was found that in such a case the mirror device is prevented from following, for example, the reflection of a cloud where, for example, more light can be received under a different position. Waiting for a longer period of time has found that, for example, the cloud moves away and a considerably new position has to be found that may be better.

Preferably, the control is adapted to measure the at least two, preferably 5, pairs of substantially simultaneously measured values of light intensities by the first and the second before, preferably immediately before, each, preferably periodically, searching for the adjusted optimum position light sensor. This is preferably done by measuring the light intensities during a period shortly before searching for the optimum position, for example 30 seconds before determining the optimum position. More preferably, this is done, for example, 5 times with 5 to 6 seconds between each measurement during the 30 seconds for finding the adjusted optimum position. In preferred embodiments, the control is provided for when the first and the second light sensor are saturated by the radiation of the sun when by turning the mirror device the comparison value no longer exceeds the predetermined limit, to control the motor so that it causes the mirror device to continue to rotate again, preferably for a predetermined time and / or angle. Such a control also makes it possible to remedy an incorrect position caused by the saturation of the light sensors.

The invention also relates to a light control system network of different light control systems according to the present invention wherein the respective central processing units of the respective light control systems are connected to each other. In such a system it becomes possible to centrally control and / or follow up the various light control systems, for example via an interface. Preferably there is a separate central processing unit for each building. The various central processing units are, for example, connected via a computer network, for example the internet. The light control system network preferably also comprises a central computer server to which the various central processing units are connected. The connection to the central Computer server can for instance comprise a wireless connection such as, for example, a 2G / 3G, WiFi, etc. connection, but can also be connected by means of a physical connection.

The invention also relates to a method for operating a light control system according to the present invention, wherein the processing unit converts the light intensity measured by the light sensors to an expected illuminance at a predetermined location in the building and controls the artificial light source accordingly in order to operate at the predetermined location to obtain a predetermined illuminance.

According to preferred embodiments of the present invention, the processing unit determines an expected illuminance at the predetermined location in the building based on the light intensity measured by the light sensors. Such a configuration makes it possible to determine the expected illuminance in a sufficiently accurate manner at the predetermined location in the building.

According to preferred embodiments of the present invention, the processing unit is provided to take one or more of the following factors into account when determining the expected illuminance: the height at which the mirror device is placed above the floor of the predetermined location, the number of windows around the predetermined location, etc.

For example, on the basis of previous measurements for the specifically used light sensors and the specifically used light dome, it is determined how a measured light intensity on the light sensors is related to a certain reference luminous flux at 1 meter below, for example, the lower part of the dome, for example the ceiling of the building. By dividing this reference luminous flux by measuring the height squared to the predetermined location from the location for which the reference illuminance was determined, the illuminance can be determined at the predetermined location. When subsequently the illuminance is actually measured at the predetermined location, the measured illuminance can be correlated with the illuminance determined on the basis of the measured light intensity by a correlation factor. By subsequently multiplying the illuminance determined on the basis of the measured light intensity with the correlation factor, it was found that a good approximation can be obtained of the real illuminance at the predetermined location on the basis of the illuminance on the light sensors determined on the basis of the measured light intensity. of the skylight.

According to preferred embodiments of the present invention, the light control system comprises at least two light domes and the processing unit comprises a central processing unit and a local respective processing unit for each of the respective light domes, the local processing units being connected to the central processing unit and the central processing unit being connected to the artificial light source, wherein the respective local processing units control the light intensities measured by the respective light sensors in the respective light domes and the central processing unit is sent on the basis of the respective light intensities processed by the local processing units to the central processing unit of the artificial light source. Such a configuration allows the local processing units to be provided to provide control. An adjusted optimum position of the mirror device and the central processing unit is provided to control the artificial light source to provide more optimum illumination of the predetermined location. Although the connection between the central processing unit and the local processing unit can for instance take place via an electrical signal over an electrically conductive wire and the connection thereto comprises a physical communication network, for example via a physical computer network, the connection can also be established by means of a wireless communication network and the connection thereto comprises a wireless communication network. A wireless communication network has the advantage that no physical network has to be provided and that remote light domes can also be included in the light control system.

According to preferred embodiments of the present invention, the light control system comprises at least two artificial light sources. In such a configuration, the control of the artificial light sources is considerably simplified compared to the previous manual control of the artificial light sources since, especially in the case of a plurality of artificial light sources, the control of the artificial light sources becomes more complicated and thus the risk of unnecessary energy consumption for driving the artificial light sources increases.

According to preferred embodiments of the present invention, the processing unit determines on the basis of the light intensity measured by the first and the second light sensor and the period of time that the artificial light source is driven the amount of energy that is saved compared to a continuous control of the artificial light source. The performance of the light control system can be determined and / or monitored on the basis of the determined amount of energy saved compared to continuous control of the artificial light source. In addition, it becomes possible for a user of the light control system to charge a fee based on the determined energy saved, making it possible, for example, for an installer of the light control system to charge a user of the light control system an amount for the use of the light control system based on the amount of energy saved by the user that would normally have been used by the artificial light source or sources. It also becomes possible to monitor the operation of the system via the same route and thus to monitor and possibly improve the permanent performance or to carry out repairs via the same route without being physically on site (for example uploading new software, resetting local or central processing unit, engine and mirror re-initialization, etc.).

The invention will be further elucidated with reference to the description below and the accompanying figures.

Figure 1 shows a longitudinal section of a preferred embodiment of a light dome of a light control system according to the invention.

Figure 2 shows a cross-section of a preferred embodiment of a light dome of a light control system according to the invention.

Figure 3 shows a perspective view of a preferred embodiment of a light dome of a light control system according to the invention.

Figure 4 shows a perspective view of a transmission of a preferred embodiment of a light dome of a light control system according to the invention.

Figure 5 schematically shows a printed circuit board with a control system for a preferred embodiment of a light dome of a light control system according to the invention.

Figure 6 shows an overview of a light control system according to the present invention.

The light dome shown in Figs. 1-3 comprises a prismatic lens 10 at the top of the roof opening, a light shaft 11 with reflective walls through the roof opening and a pyramid lens or second prismatic lens 12 at the bottom of the roof opening, which together form a daylight diffusing device, for spreading daylight / sunlight that falls in at the top of the roof opening in the building. At the top of the prismatic lens is a rotatably mounted mirror device 1, for reflecting incident daylight and / or sunlight through the light shaft 11 under a transparent dome 13.

The transparent dome 13 is for example manufactured from transparent high-quality polycarbonate (with a double UV coating), or another transparent material known to the person skilled in the art. The base surface of the dome 13 is square, but if desired this can also be circular or have a different shape if the person skilled in the art considers this suitable. The dome preferably forms an airtight seal at the top of the whole and functions as a weatherproof shield for the mirror device. The dome is preferably attached with a combination of glue and screws to prevent burglary.

The light shaft 11 has, for example, side walls made of SPO material or sheet material that is given a highly reflective white coating (based on zirconium as an environmentally friendly alternative to reflective mirror foil) and is sealed at the top and bottom by specially made-to-measure optical elements. The upper element is the prismatic lens 10, a flat polycarbonate lens with a pattern for optimum light capture and transmission. The lower element is, for example, prismatic, pyramidal lens 12, a polycarbonate pyramidal lens, preferably with a prismatic pattern, for optimally diffusing the light within the building. Other embodiments are also possible such as, for example, a second prismatic flat lens. In addition to receiving, amplifying, reflecting and spreading the incoming light, the two lenses 10, 12 also create a stationary layer of air in the shaft 11, whereby the system is thermally insulating. The daylight-spreading device 10-12 can also be formed by any other combination of optical elements known to those skilled in the art.

A moisture-absorbing element is also preferably included in order to prevent condensation.

The mirror device 1 comprises a first arm 2 which supports a mirror 3 at an angle of preferably about 65 ° with respect to the earth's surface, and a second arm 4 on which a printed circuit board 5 with a measuring device and a processing unit is arranged. The printed circuit board 5 is arranged approximately at the height of the top of the mirror 3 and preferably directed in a direction substantially perpendicular to the earth's surface or alternatively at an angle of 45 ° to the earth's surface. It can be seen that the printed circuit board 5 with light sensors 6, 7 thereon is located above the ceiling of the predetermined location.

The mirror 3 is preferably a flat mirror but can also be a mirror with two folded corners, 1 of which is positive and 1 of which is negative. The mirror is preferably placed at a fixed angle of 50 to 80 °, more preferably 60 to 70 °, most preferably about 65 ° with respect to the earth's surface, although other angles are also possible if circumstances so require. In alternative embodiments, the mirror device generally comprises one or more flat and / or curved mirrors arranged at the same or at different angles to the earth's surface. In an alternative embodiment, the mirror 3 can also be arranged tiltably on the mirror device 1, with a tilting mechanism that can also be controlled on the basis of a measurement of light intensity, such as, for example, two sensors with an intermediate partition as described herein but with the sensors located one above the other instead of side by side.

The printed circuit board (PCB) 5, which is shown schematically in Figure 5, comprises a control system with a measuring device 6-9 for measuring the intensity of light incident on the mirror 3 and a processing unit 14 for processing the measured intensity. The measuring device is formed by a first light sensor 6 and a second light sensor 7 next to each other, with a partition 8 in the middle between them. This partition 8 forms a shadow element for creating a shadow on the first or second light sensor if the position of the mirror device 1 deviates from the optimum position at that time. In the optimum position, the light sensors 6 and 7 measure almost the same intensity. Furthermore, on the printed circuit board 5 a shielding wall 9 is arranged on top of the first and the second sensor 6, 7 for shielding light incident from that side, which is detrimental to the accuracy of the measurement. The processing unit 14 compares the intensity measured by the light sensors 6 and 7 and deduces from a difference whether the mirror device must be rotated to the left or to the right, depending on where the measured light intensity is highest. When adjusting, the mirror device 1 is rotated until the intensity measured by the sensors 6, 7 is again substantially the same.

In alternative embodiments, a combination of several light sensors can be provided, such as, for example, in addition to the first and second sensor, also a third sensor to more accurately determine the day / night distinction; According to the invention there are at least two sensors, but more than two is therefore also possible.

In the embodiment shown in the figures, the measuring device 6-9 and the processing unit are provided on the same circuit board 5. This is not essential for the invention and may also be designed differently.

The partition 8 and the shielding wall 9 are preferably also made of printed circuit board material with a black masking layer, or another material which is known to the person skilled in the art to prevent reflection of the light.

More specifically, the two light sensors 6 and 7 are light-sensitive sensors that produce a voltage that is proportional to the light incident on it. These are, for example, PV cells that can supply a certain current at light incidence, over a resistance of 1 Mohm, which leads to a voltage of approximately 3V at 30Klux. An amplifier may be placed in buffer mode after the sensor to buffer the voltage and absorb over voltage. If the sensors 6 and 7 are optimally directed towards the sun or another optimum light point, both sensors receive almost the same amount of light and they produce an equal voltage. In the other case - if the position deviates from the optimum - one of the sensors will receive more light than the other sensor and both sensors will produce a different voltage. This voltage difference is used by the processing unit to determine the optimum position.

An algorithm runs on the processing unit that is preferably constructed in such a way that, as soon as a certain minimum (eg 300 IUX or 100 Ilux) incoming light is measured, a light measurement is periodically searched (eg every minute or every five minutes) to the optimum light point. The motor is then driven to direct the mirror there. In incident darkness, when the minimum incident light is no longer achieved, the system prepares itself for the start of the next cycle. To this end, an electronic compass is preferably integrated on the printed circuit board 5 or, for example, one but preferably several such as, for example, two reed contacts are connected to the printed circuit board. A zero position can hereby be created in the east, to which the mirror device can return every 24 hours and start a new cycle from this position. Thus, each cycle starts in the vicinity of the expected optimum position and the mirror device can be brought quickly to the optimum position.

The motor 15, which drives the rotation of the mirror device 1, is preferably but not necessarily an electric stepper motor that can rotate in both directions (e.g., speed 0.2 revolutions per minute). The motor is, for example, a DC motor with a control that consists of two half bridges for control in both directions. The electrical power for the installation is supplied by the combination of a solar panel 16 with a rechargeable battery with an autonomy of, for example, 3 weeks. In this way, no mains connection must be provided. The electrical power can of course also be provided in other ways known to the person skilled in the art, such as for instance a connection to the mains voltage.

An anti-condensing agent, such as, for example, silica gel or a box with active clay, is preferably also provided in the dome for collecting possible condensation and controlling the degree of humidity in the dome.

The control unit on the printed circuit board 5 is preferably provided with a temperature sensor that measures the ambient temperature in the dome. The components used are of the industrial dass type, which means that the permitted temperature range is from -20 ° C to + 85 ° C. If the temperature in the dome should rise above 85 ° Ci, the operation will be stopped for safety reasons.

In the case that several light domes are provided in the vicinity of each other on the building, each dome preferably has its own individual control system, so that they function independently of each other with regard to the alignment of the mirror device. In this way it is not necessary to make a coupling between different domes on the same roof for aligning the mirror device. No settings (location coordinates or others) must also be entered for installation on the roof. Once the power supply (solar panel and battery) is connected, each light dome functions immediately and autonomously for directing the mirror device.

Figure 6 shows an overview of a preferred embodiment of a light control system according to the present invention.

The processing unit 14 is provided for converting the light intensity measured by the light sensors 6, 7 to an expected illuminance at a predetermined location in the building and correspondingly controlling the artificial light source 17 in order to obtain a predetermined illuminance at the predetermined location.

The light control system shown preferably but not necessarily includes at least two light domes 18, 19 and the processing unit 14 preferably but not necessarily includes a central processing unit 20 and a local respective processing unit 21, 22 for each of the respective light domes 18, 19; The local processing units 21, 22 are connected to the central processing unit 20 and the central processing unit 20 is connected to the artificial light source 17. The respective local processing units 21, 22 are provided for processing the light intensities measured by the respective light sensors in the respective Light domes 18, 19 and the central processing unit 20 are provided to control the artificial light source 17 based on the respective light intensities processed by the local processing units 21, 22 and sent to the central processing unit 20.

The connection between the local processing units 21, 22 and the central processing unit 20 as shown in Fig. 6 preferably comprises a wireless communication network 23. However, other connections are also possible, such as for example a physical network by means of, for example, cables.

As shown in Figure 6, the processing unit 14 preferably drives a plurality of artificial light sources 17.

Furthermore, figure 6 also shows a central processing location 24 where information from the central processing unit 20 ends up, for example for keeping information in order to be able to charge a user of the light control system for the use of the light control system based on the energy saved. by using the light control system of the present invention.

Also, when using the previously discussed light control system network of different light control systems according to the present invention, wherein the respective central processing units 20 of the respective light control systems can be connected to each other, for example over a network 25, more particularly a physical or a wireless network, and on these location a central gathering place can be provided, for example, to collect and maintain the data from the different light control systems and / or to host the interface. This is possible, for example, through a computer server. Such a computer server does not, of course, have to be located at a central location, but can also be located at different locations, depending on the preference of the operator of the server.

Although the present invention has been described with reference to one specific embodiment, it is clear that various modifications can be made without departing from the scope of the claims. In that sense, the description and the figures are to be regarded as examples, and are not to be construed in a strict sense.

Claims (35)

A light control system with an artificial light source and a light dome for distributing daylight in a building, comprising a daylight diffusing device (10-12) for installation in a roof opening of the building and a mirror device (1), rotatably mounted above the daylight diffusing device (10 - 12) and provided for reflecting light to the daylight diffusing device (10 - 12), the mirror device comprising a mirror (3), a motor (15) for rotating the mirror device and a control (5) for controlling the motor, such that the mirror device is brought to an optimum position in which as much light as possible is reflected to the daylight-spreading device, wherein the control comprises a measuring device (6 - 9) arranged for measuring the light intensity from incident on the mirror (3) light, the measuring device (6 - 9) being provided with a first (6) and a second light sensor (7) and a switch glue element (8) arranged for creating a shadow on the first or second light sensor (6, 7), and a processing unit (14) for processing the light intensity measured by the light sensors (6, 7), the control being provided for determining an adjusted optimum position of the light intensity measured by the first and the second light sensor (6, 7), characterized in that the processing unit (14) is provided for converting the light intensity measured by the light sensors (6, 7) to an expected illuminance at a predetermined location in the building and to control the artificial light source (17) accordingly in order to obtain a predetermined illuminance at the predetermined location. Light control system according to claim 1, characterized in that the processing unit (14) is provided to determine an illuminance on the light sensors on the basis of the light intensity measured by the light sensors and on the basis of the illuminance determined on the light sensors (6, 7) determine the expected illuminance at the predetermined location in the building. Light control system according to one of the preceding claims, characterized in that the light sensors (6, 7) are located above the ceiling of the predetermined location. Light control system according to one of the preceding claims, characterized in that the light control system comprises at least two light domes (18, 19) and the processing unit (14) a central processing unit (20) and a local respective processing unit (21, 22) for each of comprises the respective light domes (18, 19), wherein the local processing units (21, 22) are connected to the central processing unit (20) and the central processing unit (20) is connected to the artificial light source (17), the respective local processing units (21, 22) are provided for processing the light intensities measured by the respective light sensors in the respective light domes (18, 19) and the central processing unit (20) is provided on the basis of the light intensity measured by the local processing units (21, 22). ) processed respective light intensities forwarded to the central processing unit (20) and the artificial light source (17) ) to guide. Light control system according to claim 4, characterized in that the connection between the local processing units (21, 22) and the central processing unit (20) comprises a wireless communication network (23). Light control system according to one of the preceding claims, characterized in that the light control system comprises at least two artificial light sources. Light control system according to one of the preceding claims, characterized in that the control (5) is provided to determine the adjusted optimum position when a comparison value calculated per basis of the light intensities measured by the first and the second light sensor respectively exceeds a predetermined limit and for periodically determining the comparison value. Light control system according to one of the preceding claims, characterized in that the comparison value is equal to the absolute value of a value based on a difference of light intensities measured by the first and the second light sensor respectively divided by a value based on a sum of of the light intensities measured by the first and the second light sensor, respectively. Light control system according to one of the preceding claims, characterized in that the control (5) is provided to determine the adjusted optimum position by turning the mirror device on the basis of a reference value calculated on the basis of the light intensities measured by the first and the second respectively light sensor. Light control system according to one of the preceding claims, characterized in that the reference value is equal to a quotient of a value based on a difference of light intensities measured by the first and the second light sensor, respectively, and a value based on a sum of light intensities measured by the first and the second light sensor, respectively. Light control system according to one of the preceding claims 9 or 10, at least in combination with claim 7, characterized in that the control (5) is provided, as long as the comparison value exceeds the predetermined limit, to control the motor in such a way that the mirror device according to the reference value rotates until the comparison value does not exceed the Predetermined limit. Light control system according to one of the preceding claims, at least in combination with claim 8 or 10, characterized in that the values are determined on the basis of a difference and sum of light intensities measured by the first and the second light sensor respectively by taking an average of at least ten at least two differences and sums of at least two pairs of light intensities measured by the first and the second light sensor, respectively, at different times. A light control system according to claim 12, characterized in that the control is adapted to measure the at least two pairs of substantially simultaneously measured values of light intensities by the first and the second light sensor for looking up the adjusted optimum position. A light control system according to claim 12 or 13 at least in combination with claim 7, characterized in that the control is provided as long as the comparison value exceeds the predetermined limit and replaces at least one of the at least two pairs of values measured by the first and the second light sensor by a few values measured by the first and the second sensor after or during the rotation of the mirror device. Light control system according to one of the preceding claims, characterized in that the control is provided for periodically looking up the adjusted optimum position. Light control system according to claim 15, characterized in that the control is provided to look up the adjusted optimum position after an extended period if the measured light intensities are insufficiently different from each other as a function of time. Light control system according to one of the preceding claims, at least in combination with claim 7, characterized in that the control is provided for when the first and the second light sensor are saturated by the radiation of the sun when the comparison value is rotated by rotating the mirror device no longer exceeds a certain limit, to control the motor in such a way that it causes the mirror device to rotate again. Light control system according to one of the preceding claims, characterized in that the first and second sensor (6-7) are arranged next to each other on a printed circuit board (5) and the shadow element is formed by an intermediate wall (8) midway between the first and the first second sensor. Light control system according to claim 18, characterized in that a shielding wall (8) is arranged on the printed circuit board (5) at the top of the first and the second sensor. Light control system according to one of the preceding claims, at least in combination with claim 4, characterized in that the measuring device (6-9) and the local processing unit (14) are located on the same printed circuit board (5). Light control system according to one of the preceding claims, characterized in that the mirror (3) is arranged at an angle of 50 to 80 ° with respect to the earth's surface. Light control system according to one of the preceding claims, characterized in that the mirror (3) is arranged at an angle of 60 to 70 ° with respect to the earth's surface. Light control system according to one of the preceding claims, characterized in that the mirror (3) is arranged at an angle of approximately 65 ° with respect to the earth's surface. Light control system according to one of the preceding claims, characterized in that the measuring device (6-9) is arranged substantially perpendicular to the earth's surface. Light control system according to one of the preceding claims 1 to 23, characterized in that the measuring device (6-9) is arranged at an angle of approximately 45 ° on the earth's surface. Light control system according to one of the preceding claims, characterized in that the mirror device (1) comprises a support with a first arm (2) for supporting the mirror (3) and a second arm (4) for supporting the measuring device (6-9) on top of the mirror. Light control system according to one of the preceding claims, characterized in that the light dome comprises a transparent dome (13) mounted over the mirror device (1) to protect it against weather conditions. Light control system according to one of the preceding claims, characterized in that the daylight diffusing device comprises a prismatic lens (10) at the top of the roof opening, a light shaft (11) with reflective walls through the roof opening and a pyramid lens (12) at the bottom of the roof opening. Light control system according to one of the preceding claims, characterized in that the control (5) comprises means for determining a zero position, for determining a zero position in which the mirror device is directed substantially to the east. Light control system according to one of the preceding claims, characterized in that the control (5) is provided for looking up an initially optimum position during a complete revolution of the mirror device. The light control system according to claim 30, characterized in that the control (5) is provided for looking up the initially optimum position when the measured light intensity exceeds a predetermined second limit and for periodically determining the adjusted optimum position. Light control system according to one of the preceding claims, characterized in that the control (5) is provided for adjusting the position of the mirror device when the difference in intensity measured by the first and second sensor exceeds a predetermined third limit. A light control system network of different light control systems according to any one of the preceding claims, wherein the respective central processing units (20) of the respective light control systems are connected to each other. Method for operating a light control system or light control system network according to one of the preceding claims, characterized in that the processing unit (14) converts the light intensity measured by the light sensors (6, 7) to an expected illuminance at a predetermined location in the building and correspondingly controls the artificial light source (17) to obtain a predetermined illuminance at the predetermined location. Method for operating a light control system or light control system network according to claim 34, characterized in that the processing unit (14) is based on the light intensity measured by the first and the second light sensor (6, 7) and the length of time that the artificial light source (17) ) the amount of energy that is saved is determined in relation to a continuous control of the artificial light source (17).