FR2983620A1 - Base element e.g. French window, for video image display device used on e.g. outer front wall of building, has LEDs to emit light via front pane, where zone of rear surface of pane located against LEDs is free from photovoltaic element - Google Patents

Abstract

The base element (8) has front and rear panes (10, 12) e.g. organic glass panels, arranged opposite to one another. A photovoltaic element (38) is placed on a rear surface (32) of the front pane. An electronic circuit includes LEDs (18) to emit light through the front pane. A zone of the rear surface of the front pane located against the LEDs is free from the photovoltaic element. The photovoltaic element is a photovoltaic material, photovoltaic cells, or an amorphous silicon photovoltaic layer. Collectors recover electricity produced by the photovoltaic element.

Description

The invention relates to light-emitting diode display panels, especially large panels extending over all or part of the facade of a building. It is known to form on the facade of a building a video image display device in which the display is performed by means of light emitting diodes or LEDs. The device can have very large dimensions to cover an area of several hundred or several thousand square meters. Such a display has many advantages. First, it is embedded in the architecture. Thus, it is the building that supports the display, the latter taking advantage of the presence of the building to extend on a great height. The diodes consume relatively little energy. However, they produce an image with pronounced contrast and perfectly visible even in daylight and in full sun. The diodes allow the display of a fast succession of images or a film with a very satisfactory rendering. Last but not least, the diodes and the electronic circuit that carries them on the facade of the building can be placed without obstructing it for the occupants of the building. Indeed, the diodes can be arranged on supports widely spaced from each other that preserve most of the view for the occupants and let in all the natural light desired.

Thus, it is common to have the circuit inside the building facing windows forming the facade. The lighting emitted by the diodes is transmitted directly to the outside. The resulting image is visible to people outside the building. In this arrangement, the electronic circuit carrying the diodes is protected from bad weather and moisture in particular. The power consumption of such a device can be between 100 watts and 400 watts per square meter per hour. Although it is reasonable in comparison to other large video image display modes, this level of consumption remains high, so it does not comply with certain regulations and certifications required for architecture, relating to energy savings and respect for sustainable resources. An object of the invention is therefore to provide a screen that is more responsive to the constraints relating to the preservation of the environment. Document FR 2 945 659 describes a display element comprising an electronic circuit comprising diodes. The display element comprises an elongate support carrying the circuit and photovoltaic cells, the circuit and the photovoltaic cells extending on different faces, the faces being inclined relative to each other at an obtuse angle. . This display element has the disadvantage that the surface of the photovoltaic cells is limited, as well as the energy that they can produce. The present invention aims to remedy these disadvantages.

The invention thus relates to an element, in particular for facade, characterized in that it comprises: - at least two windows facing one another, including a front window and a first rear window, a photovoltaic element being disposed on the rear face of the front pane, and - at least one electronic circuit comprising light-emitting diodes able to emit light through the front pane, the rear face of the front pane being free of photovoltaic element opposite the diodes. There is no photovoltaic element in the areas of the rear face of the front pane located in front of the light emitting diodes, that is to say in front of the light-emitting diodes, to allow the passage of light issued by them. In this way, the light emitted by the diodes is fully visible from the outside. Thus, when looking at the facade from the outside, we see the diodes without significant decrease in the light emitted. The photovoltaic element is disposed on all or part of the rest of the rear face of the front glass, which allows to collect the maximum light and optimize the electrical energy produced.

The photovoltaic element can be a photovoltaic material, photovoltaic cells. The photovoltaic element may be a photovoltaic amorphous silicon layer.

The electricity produced by the photovoltaic element can be recovered by collectors. Each electronic circuit can be arranged between the front window and the first rear window. The element may comprise at least three windows facing each other, including a second rear window located behind the first rear window. In this case, each electronic circuit can be arranged between the front window and the first rear window or between the first rear window and the second rear window. At least some of the diodes may be arranged such that a principal direction of light emission from each diode is locally perpendicular to a plane of the front window. This embodiment is adapted to make the element an image display device such as an animated image from a video signal. The invention also relates to a device, in particular display, which comprises several elements according to the invention. The invention also relates to a building wall, including a facade, which comprises at least one such display device. It is also provided according to the invention a building which comprises at least one such wall. Other characteristics and advantages of the present invention will appear more clearly on reading the following description given by way of illustrative and nonlimiting example of a method according to the invention, the description being made with reference to the appended drawings in which: FIG. 1 is a perspective view of a building in its environment and whose facade comprises a display device according to one embodiment of the invention; FIG. 2 is a view showing a part of this facade as viewed from inside the building of FIG. 1; FIG. 3 is a partial sectional view along a vertical plane of the facade of the building of FIG. 1; FIG. FIG. 5 is a partial perspective view of an electronic circuit of the facade of FIG. 3; FIGS. 6 and 7 are views similar to FIG. Figure 4 shows in two other embodiments, and - Figure 8 is a diagram illustrating the display device. With reference to FIGS. 1 to 5, a first embodiment of the invention will be described. The building 2 illustrated in Figure 1 has on its respective sides 15 several facades which are here four in number. One of them, the facade 4, is a facade according to the invention insofar as it comprises a video image display device. This device 6 is visible in particular in Figures 2 to 4. The facade comprises several building elements which are here 20 formed by windows 8. These windows 8 extend from top to bottom depending on the height of the facade of the building and d one side to the other of the facade according to its width. The windows 8 extend in the extension of each other in both directions and for example in the same plane for most of them, or for all if the facade is flat. Each window 8 comprises two panes 10, 12, particularly visible in FIG. 4. By "window" is meant in this case a transparent panel made of organic or mineral glass. But it can realize such a window in a material other than glass and for example a synthetic material such as plastic. The two panes 10, 12 are flat and identical to each other. They each extend in a vertical plane, facing one another, parallel to each other and at a distance from one another. Their contours are in coincidence. The windows here have a rectangular shape as shown in Figure 2. The facade 4 may have windows 8 of at least two types having in particular different dimensions. Thus, in the present example, the facade is formed geometrically by the reproduction of a rectangular mesh comprising in the upper part a low height window and in the lower part a high height window. The two windows of the mesh have the same width which is in this case about 2 meters. The height of the small window is in this case of 1.05 meter while the height of the large window is in this case of 3.05 meters. The total height of the mesh is 4.10 meters in the present example. These dimensions are given by way of example only and are not limiting. Between the two panes 10, 12 of each window 8 extends an electronic circuit 13 comprising units such as the unit 14 illustrated in part in FIG. 5. In the present example, these units are in the form of identical elongated straight bars between they. The bars 14 are here arranged horizontally in the same vertical plane, being all parallel to each other and at a distance from each other. It will be observed that the bars, as they appear in the visible zone of the window as shown in FIG. 2 (that is to say, opposite the visible part of the windows), are devoid of any connection between them or electrical or electronic connection in this visible area. The electronic circuit 13 associated with each window 8 comprises a member interconnecting the bars 14 and which is housed in a portion of the window concealed from view. For each pair of consecutive bars 14 in the succession, the space delimited between these two bars is thus left entirely free. It is delimited at its ends only by the uprights 16 of the window. Each bar 14 comprises identical diodes 18 and regularly spaced from each other. In the present example, the center distance e, designating the distance between the axes of the successive diodes, is 5 centimeters. This spacing is preferably chosen to be large in comparison with the diode's own dimensions. Thus, if the diameter of each diode is less than 1 centimeter, it is seen that this center distance is equal to five times the diameter of the diodes. We can freely choose the value of the inter-axis (pixel pitch in English language) depending on the circumstances (especially depending on the orientation of the facade with respect to the sun), knowing that the closer the diodes are some of other, the brightness of the device increases. The bar 14 comprises a support 20 or substrate to which the diodes are attached. In this example, the support 20 is semi-transparent. Each bar 14 also carries electronic components 22,24 known in themselves and which serve for the display of the image by the diodes 18. These components include in particular processors forming drivers 22. Each driver is able to control several diodes 18 independently of each other to display with the element 8 a portion of a moving image. As can be seen in particular in FIGS. 5 and 6, the diodes thus form an array of pixels and each will constitute one of the elements of the image to be displayed. Preferably, the diodes are of SMD type (surface mount device in English language). Each diode is surmounted by a primary optical element of the lens type which makes it possible to direct the light emitted by the diode towards the privileged zones for the vision of the screen. In this case, it is to send the light in opposite directions to that of the building and also not to send the light to the sky. It may be provided to replace each diode 18 with a set of three or more diodes capable of emitting beams of respective colors red, green and blue. The overall beam produced by this group can therefore take various colors depending on the command sent to each of the three diodes. This is a RGB type display (red, green and blue). Each of the bars 14 can therefore emit several light beams of different colors. The circuit 13 may incorporate a layer of a transparent material which is in this case flexible silicone, whose function is to avoid the thermal bridges between the two panes 10,12. This protective layer extends from the side of the circuit opposite the support 20. It therefore extends on the external side with reference to the position of the circuit when it is in place on the facade. 4, the front face 31 of the front pane 10, the rear face 32 of the front pane 10, the front face 33 of the rear pane 12 and the rear face 34 of the rear fast 12. bars 14 are housed in a closed sealed chamber 36 delimited between the faces 32 and 33, the panes 10 and 12 forming a double glazing. The rear face 32 of the front pane 10 is covered on certain areas of a photovoltaic element 38. The photovoltaic element 38 is advantageously a photovoltaic material. The photovoltaic material may be an amorphous silicon layer with photovoltaic properties. In this configuration, the number of Kw / h necessary for the operation of the LEds screen operating in video mode is of the same order as the number of Kw / h produced by the glass provided with a photovoltaic amorphous silicon layer. where the result of a "zero" consumption or self-powered screen. The photovoltaic amorphous silicon layer applied to glass has a degree of transparency of between 10 and 30% depending on the thickness of the layer and its color. The layer is applied as a varnish. The photovoltaic material 38 may extend over the entire face 32 except in zones delimited opposite the diodes 18. Each of these latter is arranged to produce a light beam 40 whose main axis is perpendicular to the faces 31 and 32 The beam 40 emitted by the diode thus enters the front window 10 via its rear face 32, passes through the thickness and leaves it through its front face 31 to be diffused outside the element and the building. Given the absence of material 38 to the right of the diode, the beam does not cross the material. On the other hand, part of the rays of the sun 42 coming into contact with the element 25 penetrate into the latter through the face 31 of the front pane 10 and are reflected on its face 32 and sent outwards in view of the presence of the material 38 In view of the filtering and reflection effected by the material 38, the solar radiation does not cause a steep rise in temperature in the chamber 36. The rear window 12 makes it possible at least partly to prevent entry into the chamber. building parasitic radiation from the diodes 18, returned to the interior of the building by the face 32 and may otherwise interfere with the occupants of the building.

Another embodiment is illustrated in FIG. 6. The element 8 is identical to that of FIG. 4, except that it comprises an additional flat pane 15 extending in this case behind the rear pane 12. The window 10 is still the front window, the window 15 constitutes the second 5 rear window and the window 12, interposed between the two previous, is the first rear window. The second rear window 15 defines with the first rear window 12 a rear chamber 37, the chamber 36 forming a front chamber and receiving, as previously, the circuits 13 carrying the diodes. This is an element forming a triple glazing, the two chambers 36 and 37 10 being closed and sealed. The second rear window 15 also prevents at least part of the entry into the building spurious radiation from the diode 18, returned to the interior of the building by the face 32 and may otherwise interfere with the occupants of the building. It assists in this function the first rear window 12 which could in certain cases fulfill this role insufficiently. In another embodiment illustrated in FIG. 7, the element 8 is identical to that of FIG. 6, except that the bars 14 carrying the diodes extend this time into the rear chamber 37 and no longer into the chamber. Before 36. The light beam 40 emitted by each diode thus crosses this time in the following order: a part of the rear chamber 37, the rear face 34 of the first rear window 12, the thickness of the latter; The front face 33 of the first rear window 12, the chamber 36, the rear face 32 of the front window 10, the thickness of the latter, and the front face 31 of the front window 10 by means of which it leaves element 30 to be broadcast outside the building. Here again, the material 38 does not extend to the right of the diodes so as not to disturb the diffusion of their beam.

In order to improve the penetration of the beam 40 into the window, it is possible to provide on the entry face, in addition to the coating 38, a treatment and / or a layer of material forming another coating and promoting the entry of the light into the window. window. This material may for example be provided in the form of a film applied against the face 32 of the front pane 10. This is for example a film from the 3M company called "3M (TM) Scotchcal (TM) Transparency 3630 series ". It is also possible to provide such a material by screen printing or in liquid form on the face 32. This embodiment is not intended to display an image portion 10 by the element 8 but the illumination of the building by the indirect diffusion of the light of diodes in the form of a halo for example. As illustrated in FIG. 3, the lower edge and the upper edge of each window 8 extend in this case at a level or level 52 of the building 2. This level is formed here by a layer of structure, for example concrete. The windows are brought to their lower edge and to their upper edge by a pair of sections 56 fixed rigidly to one another, supporting by their front edge the two consecutive windows in the succession following the height of the building, and connected by their rear edge at level 52.

Each window 8 may comprise at the periphery a separator or spacer 48 conferring in constant spacing between the faces 32 and 33 of the panes all around the window. A sealing material such as a silicone-based glue forms a seal 50 along the edge of the two panes, between them, to seal the closed chamber 36.

As illustrated in FIG. 8, the electric current produced by the layer of photovoltaic material is recovered by batteries intended to store electricity and can be used in the (direct current) state to power the screen or This electricity is then used to feed the screen compounds, or for another use (lighting, air conditioning, sending in the network). At least some of this energy can be stored in a battery for later use in displaying the image. For example, it can be expected that during the day the screen is off and stores energy in the battery, then is turned on at night and operates using the energy provided by the battery. The basic element 8 used to constitute the device may be a bay window, a French window or a window. It may be a roof element. The wall may be an external facade, or a facade or inner wall opening for example on a patio. Element 8 may serve as an interior design element or decoration. It will be possible to consider using the invention independently of the presence of a building. The invention is applicable to buildings erected on the ground, as well as to vehicles and vehicles.

Claims (10)

REVENDICATIONS1. Element (8), especially for facade (4), characterized in that it comprises: - at least two windows (10,12) facing one another, including a front window (10) and a first rear window (12), a photovoltaic element (38) being arranged on the rear face (32) of the front window (10), and - at least one electronic circuit (13) comprising light-emitting diodes (18) able to emit light the light through the front window (10), the rear face (32) of the front window (10) being free of photovoltaic element (38) facing the diodes (18). 2. Element (8) according to claim 1, characterized in that the photovoltaic element (38) is a photovoltaic material or photovoltaic cells. 3. Element (8) according to claim 1 or 2, characterized in that the photovoltaic element (38) is a photovoltaic amorphous silicon layer. 4. Element (8) according to one of claims 1 to 3, characterized in that the electricity produced by the photovoltaic element (38) is recovered by collectors. 5. Element (8) according to one of claims 1 to 4, characterized in that each electronic circuit (13) is disposed between the front window (10) and the first rear window (12). 6. Element (8) according to one of claims 1 to 4, characterized in that it comprises at least three windows (10,12,15) facing each other, including a second rear window (15) located behind the first rear window (12). 7. Element (8) according to claim 6, characterized in that each electronic circuit (13) is disposed between the first rear window (12) and the second rear window (15). 8. Element (8) according to one of claims 1 to 7, characterized in that at least some of the diodes (18) are arranged so that a main direction of light emission (40) by each diode ( 18) is locally perpendicular to a plane of the front window (10). 9. Device (6), characterized in that it comprises several elements (8) according to one of claims 1 to 8. 10. Building wall (2), including facade (4), characterized in that it comprises at least one device (6) according to claim (9).