Patent Application
20130264948
The present invention relates to the field of the control of the light intensity in buildings.
The windows of buildings have the drawback of contributing to the heating of the buildings in summer and to their cooling in winter.
Since the mid-1990s, a large variety of insulating and solar control windows have been developed by the glass industry. Thanks to “low emissivity” or “reflecting” coatings currently on the market, high levels of thermal insulation and of solar protection can be obtained.
Nevertheless, these windows have fixed properties which cannot be adapted to the temperature and sunshine conditions.
Window glass with variable optical properties provides a solution to this problem.
These active glass panes, referred to as “intelligent glass”, have optical transmission properties that are modifiable, for example electrically.
One known solution is to use electrochromic window glass to minimize the energy consumption of the building.
US-A-2007/0067048 describes a system for controlling electrochromic windows aiming to minimize the energy consumption of the building while at the same time providing a certain brightness inside of the building.
Nevertheless, electrochromic glass modifies the spectral distribution of the transmitted light, which can be a drawback, even if a user does not necessarily realize it.
Indeed, it will be a drawback for example in a museum if the colors of the works exhibited are modified, even in an unnoticeable manner for the visitor.
Furthermore, an environment even very slightly colored can produce certain psychological effects on the nervous system. Colors with a long wavelength (red) have a stimulating effect whereas colors with a short wavelength (violet) have a calming effect. The intermediate colors (yellow, green), have a tonic effect favorable to concentration.
One aim of the present invention is to provide an active system with electro-controllable optical transmission properties for equipping a room of a building allowing the drawbacks of a spectral distribution shift of the light in the room to be avoided even if this shift is not noticeable for the user.
According to one aspect of the invention, the lighting control system comprises:
According to particular embodiments, the cell comprises one or more of the following features, taken in isolation or according to all the technically possible combinations:
Another subject of the invention is an assembly comprising an active window pane with electro-controllable optical transmission properties, a lighting device and a control system for controlling the active window pane and the lighting device, the control system being such as described hereinabove.
A further subject of the invention is a method for controlling an active window pane with electro-controllable optical transmission properties and a lighting device comprising steps consisting in:
using a coloration sensor for measuring a value representative of coloration of a light;
controlling the lighting generated by the lighting device as a function of the value supplied by the coloration sensor.
According to particular embodiments, the method comprises one or more of the following features, taken in isolation or according to all the technically possible combinations:
The invention will be better understood upon reading the description that follows, presented solely by way of example, and with reference to the appended drawing in which
The device is a system 1 for controlling the lighting of a room of a building.
The room is equipped with several active window panes 2 with electro-controllable optical transmission properties, more particularly with electrochromic glass panes, and with an electro-controllable lighting device 4.
The system for controlling the lighting 1 controls the active window panes 2 and the lighting device 4.
The system 1 described relates to a single room but, more generally, the control system 1 can control the lighting of several rooms of a building.
Electrochromic windows 2 are glass panes including an electrochemically active device chemically reacting to the application of an electrical power supply. The optical transmission of an electrochromic window 2 is thus electrically controlled.
The optical domain is understood to mean the visible, infrared and ultraviolet domains.
Many electrochromic glasses 2 exist.
They are generally classified into three categories: “all organic” or “all polymer”, “mixed”, in other words both organic and inorganic, and “all solid”, in other words generally all inorganic.
U.S. Pat. No. 5,239,406 and EP-A-0 612 826 describe for example electrochromic organic devices.
EP-0 253 713 and EP-0 670 346, EP-0 382 623, EP-0 518 754 or EP-0 532 408 describe electrochromic mixed devices.
EP-0 831 360 and WO-A-00/03290 describe all solid electrochromic devices.
Advantageously, the electrochromic device is a device referred to as “all solid”. Such a device has the advantage of being durable, since it is composed of inorganic layers. Such a device furthermore has the advantage of allowing the number of substrates to be minimized, the layers being deposited onto a single substrate.
Nevertheless, the glass panes 2 are not necessarily electrochromic; they are in general active window panes with electro-controllable optical transmission properties, for example made of gasochromic or thermochromic glass.
The control system comprises a control unit 10 equipped with a memory 12 in which programs are recorded for controlling active window panes 2, in other words the optical transmission through the active window panes 2.
It should be noted that the control of active window panes 2 is conventionally carried out by sending a setpoint voltage to the terminals of the glass panes 2, different values of voltage controlling different states of optical transmission through the glass panes 2.
The control system 1 furthermore comprises a coloration sensor 14 for the light in the room and the programs are designed to control the active window panes 2 depending on the coloration value supplied by the coloration sensor 14.
The coloration sensor 14 is advantageously placed in an area of the room where it is desired to control the coloration, for example in a work place such as an office.
The coloration sensor 14 is for example a sensor supplying a CRI value (Colour Rendering Index) for example the Ra or R96a value from the CIE (International Commission on Illumination).
As a variant, the sensor supplies a coloration value of any suitable type, for example a value in a coloration system defined by the CIE, for example a value of L*, a* and b* in the (L*, a*, b*) coloration system of the CIE or a value of X, Y and Z in the XYZ system of the CIE or a value of L*, u* and v* in the (L*,u*,v*) system of the CIE.
It should be noted that the (L*, a*, b*) system, which is widely used, characterizes a color by means of an intensity parameter L* corresponding to the luminance and of two chrominance parameters (a*, b*) which describe the color. This system has been specially designed so that the calculated distances between colors correspond to the differences perceived by the human eye. For example, the combination L* is the clarity, which goes from 0 (black) to 100 (white), the component a* represents the range of the red axis (positive value)→green (negative) going through white (0) if the clarity is equal to 100 and the component b* represents the range of the yellow axis (positive value)→blue (negative) going through white (0) if the clarity is equal to 100.
Generally speaking, the coloration sensor 14 is capable of supplying a value representative of a color or “chrominance” of the light received by the sensor, in other words of giving a relative chromatic indication to this light.
It should be noted that the term “value” is to be understood throughout the text in its wider sense. It can be a value of any suitable type. It can for example be a single numerical value, or of a set of values such as a vector or a matrix.
The term “representative” is understood to mean that this value allows information of any suitable type to be obtained on the coloration of the light being analyzed.
The control programs are capable of controlling the lighting device 4 so that it generates an illumination whose coloration is such that the lighting generated by the lighting device 4 comes close to the coloration of the light measured by the sensor 14 measuring the coloration of a reference value which is for example predetermined or calculated.
If the light transmitted by the active window panes 2 is shifted toward the blue, the light from the lighting device 4 will for example be shifted toward the red with respect to the light transmitted by the active window panes 2.
The lighting device 4 for example comprises LEDs, for example several color LEDs, in order for example to control the color of the illumination by the intensity of each color LED.
Generally speaking, this is a lighting device 4 whose coloration rebalances the coloration of the light analyzed by the coloration sensor toward a desired lighting coloration.
Advantageously, the coloration of the illumination generated by the lighting device 4 is adjustable, since it is an artificial illumination.
As a variant, however, but non-exclusively, the system 1 comprises an electro-controllable lighting device 4 supplying a natural light. This is for example a device reflecting the outside light with an adjustable angle, for example an electro-controllable venetian blind, and capable of reflecting the outside light toward the inside. The device 4 is advantageously configured and arranged for reflecting the outside light toward the ceiling of the room. This device 4 is for example positioned in front of a clear glass pane or tinted with a color chosen to come close to the light in the room of a particular color, for example of white color.
According to a first embodiment, the system 1 controls the active window panes 2 independently of the value supplied by the coloration sensor 14. The effects of the coloration are corrected but not their cause.
According to a second embodiment, the system 1 controls the active window panes depending on the coloration value supplied by the coloration sensor 14. The system thus acts on the cause if the variation of color is judged to be unacceptable, for example in view of other criteria such as the brightness in the room.
The control system 1 furthermore comprises for example a brightness sensor for supplying a value representative of brightness in the room, and/or a temperature sensor for supplying a value representative of temperature in the room, and/or a glare level sensor for supplying a value representative of glare level in the room.
The control programs are then capable of controlling the optical transmission through the active window panes as a function of the values representative of coloration, of brightness and/or of temperature and/or of glare level. It should be noted that the sensors are of any suitable type. Furthermore, a sensor for the presence of a person in the room may also be used.
The glare level sensor is for example a digital camera associated with a processing unit capable of supplying a value of glare level, for example in DGI.
As a reminder, the DGI glare level value is defined as
DGI=10 Log 10.478Σ[(Lw1.6*Ω0.6)/(Lb+0.07*ω*0.5Lw)], with
Lw=Luminance of the window (nits)
Lb=Luminance of the background (nits)
Ω=Solid angle of the window modified by the position of the source (sr)
Ω=Solid angle of the source seen from the point of observation (sr) As a variant, the evaluation of the importance of the glare level can be
carried out by using various values. These values have been developed in order to characterize the physical sensation of dazzling. These various values could be used independently or as a complement to one another:
the “Glare index” GI or BRI or BGI which is described in the article by P. Petherbridge, R. G. Hopkinson, Discomfort Glare and the Lighting of Buildings, transactions of the Illuminating Engineering society 15 (39) (1950), London, UK.
the “Discomfort Glare Rating” (DGR) associated with the “Daylight Glare Index” (DGI) described by R. G. Hopkinson, Glare from daylighting in buildings, Applied Ergonomics 3 (4) (1972).
the “Visual Comfort Probability” (VCP) described in DiLaura, David L., On the Computation of Visual Comfort Probability, Journal of the Illuminating Engineering Society, Vol. 5, July 1976, Pg. 207
the CGI and the “Unified Glare Rating System” (UGR) described by the CIE in Discomfort Glare in the Interior Lighting, Commission Internationale de l'Eclairage (CIE), Technical committee TC-3.13, Division 4, Interior Environment and Lighting design, Vienna Austria, 1992.
Generally speaking, a value of any suitable type can be used.
The brightness sensor is for example placed inside of the room. Nevertheless, as a variant, the sensor is placed outside of the building.
The temperature sensor is, for its part, preferably placed inside of the room.
The presence sensor is, as a variant, replaced by a clock, the presence in a room corresponding to a predetermined timetable.
The glare level sensor can be a brightness sensor, preferably outside of the building, associated with a clock. Indeed, the clock allows the position of the sun in the sky to be determined and thus the value of glare level as a function of the measured value of brightness.
Furthermore, the system can comprise one or more sensors of each type. The function of several sensors can also be carried out by a single device. A CCD camera can for example provide the function both of glare level sensor and of brightness sensor.
Throughout the text, the terms “a sensor A and a sensor B” should not be understood as implying necessarily two separate devices; this may be one and the same device supplying two measurements. The same applies to the term “unit”.
Lastly, the room may furthermore be equipped with screening means such as blinds, curtains, PDLCD windows, etc., the control system 1 also being capable of controlling the screening means.
As a variant, the control system only comprises one or a combination of more than one sensor from amongst the sensors hereinabove.
It should be noted that, throughout the text, the term “as a function of” should be understood in an inclusive manner and not in an exclusive manner. By way of example, the term “as a function of a coloration value” does not exclude a value of brightness, of temperature and of glare level also being taken into account.
The glare level sensor is for example a digital camera associated with a processing unit capable of supplying a glare level value, for example in DGI.
As a reminder, the DGI glare level value is defined as:
DGI=10 Log 10.478Σ[(Lw1.6*Ω0.6)/(Lb+0.07*ω*0.5Lw)] with :
Lw=Luminance of the window (nits)
Lb=Luminance of the background (nits)
Ω=Solid angle of the window modified by the position of the source (sr)
Ω=Solid angle of the source seen from the point of observation (sr)
Another subject of the invention is a room of a building equipped with at least one active window pane with electro-controllable optical transmission properties, a lighting device and a control system for controlling the active window pane and the lighting device, the control system being as claimed in any one of the preceding claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 1060626 | Dec 2010 | FR | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/FR2011/052978 | 12/14/2011 | WO | 00 | 6/17/2013 |
