FR2525394A1 - Photoelectric cell module and panel - includes cells immersed in liquid which absorbs unsuitable radiation for re-emission within response range of cells - Google Patents

Abstract

The photoelectric cell module comprises a flat shallow dish (10) made of clear material, with a rigid transparent glass or synthetic plate (50) fixed over it to define a sealed chamber. A transparent liquid fills the chamber, and a number of photoelectric cells (30) are immersed in the liquid, and attached to the flat base of the container. The cells are joined together in series by electrical connections (32) with two wires passing out through the base for external connection. The transparent liquid is chosen to have a high coefficient of thermal conductivity, and a low freezing point. It may also absorb radiation outside the normal response range of the cells, and re-emit radiation to which the cells are sensitive.

Description

 The present invention relates to photo voltaic cells, or photocells.

 We have already known for many years cells formed of a semiconductor material having a PN junction capable of transforming light radiation into electricity, according to the principle known as photovoltaic effect. Such photovoltaic cells or photocells, are commonly constituted by disks, for example of silicon, a few centimeters in diameter and a few tenths of a millimeter thick. A PN junction is made on one of the so-called face faces. before; a metal collecting grid is arranged on this front face, while the rear face is completely metallized.

 In order to make such photovoltaic cells practical, it has been proposed to produce modules made up of a plurality of photovoltaic cells connected to each other, for example in series.

 The photovoltaic cell modules which have hitherto been proposed are produced by encapsulating the photovoltaic cells in a flexible resin, such as a transparent silicone resin, preferably stabilized with ultraviolet rays, which is deposited on a polyester support, or sandwiched between two glass plates, or a glass plate and an insulated aluminum plate.

 However, it has been found that such modules have numerous drawbacks.

 In particular, resins of the silicone type are expensive. It turns out that despite the numerous researches which have been carried out in the field of solar modules, and in particular modules with photovoltaic cells, to reduce the volume of resin used, the price of the resin used for the realization of a module represents a non-negligible part of the total cost of producing it.

 In addition, such resins are difficult to process and require specialized personnel.

 On the other hand, the photovoltaic cells being completely encapsulated in the resin, it is easy to understand that any repair of the module is delicate.

 Finally, it has frequently been found that, since the various photovoltaic cells making up a panel do not strictly have the same characteristics, it sometimes happens that some of said photovoltaic cells behave not as a generator, but as a receiver, because they are polarized in reverse; in such a case, the photovoltaic cells in question heat up, which causes the creation of blisters in the layer of resin enveloping the deficient photovoltaic cell, until causing a deterioration of the panel which makes it totally unusable.

 The present invention now comes to propose a new module of photovoltaic cells which overcomes the aforementioned drawbacks.

 The module according to the present invention comprises a generally flat sheet metal bowl, internally enamelled and of light color, a transparent rigid plate fixed on the bowl at the opening contour thereof, to define with the bowl a sealed chamber , a transparent liquid which fills the chamber formed by the bowl and the transparent rigid plate, as well as a plurality of photovoltaic cells immersed in the liquid, fixed on the flat base of the bowl and connected to each other by electrical connections including two to the less are accessible outside the module.

 The transparent rigid plate is preferably a glass or plastic plate.

 According to an alternative embodiment, the transparent rigid plate is bonded to the contour of the bowl, using a flexible adhesive.

 Likewise, the photovoltaic cells are glued to the flat base of the bowl.

 Advantageously, the liquid which fills said sealed chamber has a high coefficient of thermal conduction and a low freezing point. According to a preferred embodiment, the liquid contains ethylene glycol.

 According to another alternative embodiment, the liquid contains a compound capable of absorbing electromagnetic radiation whose wavelength is located outside the sensitivity spectrum of photovoltaic cells, and in re-emitting electromagnetic radiation whose wavelength is closer to the maximum sensitivity of photovoltaic cells.

 The present invention also extends to solar panels comprising a plurality of modules of the aforementioned type, extended horizontally and inclined to the vertical so that the transparent rigid plate is directed upwards, the modules being spaced apart; on the other hand, the panel is completed with elements interposed between said modules, substantially horizontally elongated, inclined on the vertical symmetrically with respect to the modules and whose lower surface is endowed with retro-diffusing properties.

Other characteristics and advantages of the present invention will appear on reading the detailed description which follows, and with reference to the appended drawings, which must be considered as incorporated into the description by the reference given to them here, and on which
FIG. 1 represents a schematic perspective view of a module of photovoltaic cells according to the present invention,
FIG. 2 represents a cross-sectional view of the module of FIG. 1, according to the section plane referenced Il-Il in this figure,
FIG. 3 represents a view in longitudinal section of the end of the module shown in FIG. 1,
- Figure 4 shows a schematic view in vertical cross section of a panel representing an example of implementation of the invention.

 As shown in FIG. 1, the module 1 of photovoltaic cells according to the present invention comprises a generally flat bowl 10, made of sheet metal, at least internally enamelled and of light color. Incidentally, said sheet metal bowl can be glazed over its entire surface.

 According to a preferred embodiment, the bowl 10 made of sheet metal, is covered with a layer of white enamel.

 More specifically, the bowl 10 consists of a rectangular flat base 11 or bottom of the bowl, and ledges 12 projecting from one side of the base 11 at the periphery thereof.

 A transparent rigid plate 50 is fixed to the bowl 10, at the opening contour of the latter defined by the flanges 12.

 The transparent rigid plate 50 is a glass plate, preferably of tempered glass, or of synthetic material.

 The method of fixing the transparent rigid plate S0 to the contour of the bowl 10 must be such that said transparent rigid plate 50 defines, with the bowl, a perfectly sealed chamber intended to receive a transparent liquid 40.

 On the other hand, as shown in FIG. 1, a plurality of photovoltaic cells 30 are immersed in the liquid and fixed on the flat base 11 of the bowl 10.

 In Figure 1, there are shown four photovoltaic cells 30 in the form of discs. Of course, the number and the shape of said photovoltaic cells 30 can be chosen arbitrarily.

 As is more precisely represented in FIG. 2, on which we find the bowl 10 formed of a flat base 11 and rims 12, as well as the transparent rigid plate 50, the photovoltaic cells 30 are preferably bonded to the flat base 11 of the bowl 10, using a drop of suitable glue (diagrammatically shown 61 in FIG. 2), such as an adhesive based on silicone elastomer with crosslinking by humidity.

Preferably, the transparent rigid plate 50 is bonded to the bowl 10 (as is schematically represented in FIGS. 2 and 3), # 1 using any suitable glue
Advantageously, the adhesive used to secure the transparent rigid plate 50 to the bowl 10 is a flexible adhesive, so as to easily absorb the thermal expansions of the bowl 10 and of the transparent liquid contained in the sealed chamber formed by the bowl 10 and the transparent rigid plate 50.

 According to a particular embodiment given by way of nonlimiting example, the adhesive used is a silicone elastomer with crosslinking by humidity (acetic reaction) possibly added with fungicide to avoid attack in time by fungi. The temperature resistance of such an adhesive is of the order of -600C to + 2500C. This adhesive adheres to the transparent rigid plate 50 and the enamel covering the sheet of the bowl 10, remains flexible and therefore absorbs any expansion of the filling liquid. However, this adhesive does not withstand a temperature of the order of 3000C, temperature which can easily be reached using a conventional soldering iron used in the field of electronics, which makes it particularly easy to dismantle the module, so as to access the photovoltaic cells 30 and possibly do so. troubleshooting the module.

Tests in which glue sold by the company "Dow Corming Vending" under the brand was used
AQUARIA have given full satisfaction.

 There is schematically shown in Figure 1 the metal collecting grid 31 made on the front face of the solar cells 30. Said photovoltaic cells 30 are interconnected by electrical connections 32. More specifically, the electrical connections 32 connect the metal grid 31 of a photovoltaic cell 30, at the completely metallized rear face of the photovoltaic cell 30 which is adjacent thereto, and so on, so as to connect in series the various photovoltaic cells 30 composing the module. Of course, it is also possible to design a connection of the photovoltaic cells 30 in parallel, the particular connection mode established between the photovoltaic cells 30 must be determined as a function of the characteristics desired for the module.

 As also appears in FIG. 1, the extreme electrical connections 33 connected respectively to the metallic collecting grid of one of the extreme photovoltaic cells, and to the completely metallized rear face of the other extreme photovoltaic cell are accessible inside the module. , so as to connect the photovoltaic cell module, to any appropriate load, such as a charge regulator, an accumulator or a receiving device.

 As shown in FIG. 3, the Applicant has found that in order to simply carry out the passage of said electrical connections 33 between the rim 12 of the bowl 10 and the transparent rigid plate 50, while achieving perfect sealing of the chamber defined between the bowl 10 and the transparent rigid plate 50, it was advantageous to design the outlet connections 33, in the form of flat wires which run along the inner and outer surface of said flange 12, and are embedded in the glue 60 intended to ensure the fixing of the transparent rigid plate 50 on the bowl 10.

 According to another advantageous variant embodiment, not shown, the outlet connections 33 can be formed of insulated bolts which pass through the sheet making up the bowl 10.

 Preferably, the Liquid 40 has a high thermal conduction coefficient, so as to correctly distribute the heat capable of being dissipated by some of the photovoltaic cells 30 and avoid excessive heating thereof.

 On the other hand, it is advantageous for the 4G liquid to have a low freezing point.

 The Applicant has in particular found that filling the sealed chamber defined between the transparent rigid plate 50 and the bowl 10 using ethylene glycol was entirely satisfactory.

 It is easily understood that the module according to the present invention totally eliminates the various drawbacks noted on the modules of conventional photovoltaic cells.

 In particular, the liquid 40 such as ethylene glycol, or even water, which can be used is commonly available commercially and particularly inexpensive.

 On the other hand, the filling of the module can be carried out, and does not require specialized personnel. On this point, it may be advantageous to provide at the level of the flat base 11 of the bowl 10 at least ~ one filling and emptying orifice (referenced 13 and 14), which can be closed, during use at l using all suitable classic elastomer plugs.

 In addition, the module can easily be repaired since it suffices to separate the transparent rigid plate 50 from the bowl 10 to access the photovoltaic cells 30.

 Finally, the liquid contained in said sealed chamber makes it possible on the one hand to ensure a substantially homogeneous thermal distribution in the module, on the other hand, to absorb the mechanical stresses applied to the module, and thus to avoid mechanical stresses are applied to the photovoltaic cells, which makes it possible to handle the modules in accordance with the present invention much more easily than the modules previously proposed, in which the cells were encapsulated in a layer of silicone resin, and for which it was advisable to take great care in handling to avoid damage.

 On the other hand, we know that the emission of electromagnetic radiation produced by the sun, takes place along a wavelength spectrum, distributed substantially as follows 3% less than 0.3ytm (ultra-violet), 42% between 0.3 and 0.7 m (visible light), 55% greater than 0.7 m (infrared).

 Whereas, in general, the photo-voltaic cells have a maximum of sensitivity for wavelengths located in the visible light range (0.3 to 0.7ytm). Thus, selenium cells have a maximum sensitivity for radiation with a wavelength of about 0.6jkm, cadmium telluride cells have a maximum sensitivity for a wavelength of around 0.7 # in, while silicon solar cells tend to have maximum sensitivity for a wavelength close to 0.75 m.

 On the other hand, it is known that in cloudy weather, the electromagnetic radiation received, which comes from the sun, tends to become poorer in infrared and electromagnetic radiation in the visible domain, partly absorbed by the clouds.

 For these reasons, it is advantageous for the liquid to contain a so-called Udopant compound capable of absorbing electromagnetic radiation whose wavelength is far from the sensitive spectrum of the cells, in order to re-emit electromagnetic radiation whose wavelength is closer to maximum sensitivity of photovoltaic cells 30. More precisely, such compounds must be capable of absorbing electromagnetic radiation whose wavelength is substantially less than 0.3> ~ m or substantially greater than 0.8 m, and re-emit electromagnetic radiation whose wavelength is substantially in the visible range, that is to say between 0.3 m and 0.8 m.

 According to an advantageous embodiment shown in Figure 4, there is provided a solar panel 70 which comprises a plurality of modules 1 conforming to the module shown in Figure 1, elongated substantially horizontally and inclined to the vertical, referenced OO, so that the transparent rigid plate 50 is directed upwards, and so that the modules 1 are spaced apart. Elements 71 horizontally elongated, inclined vertically symmetrically with respect to the modules 1 and whose lower surface is endowed with retro-diffusing properties, are interposed between said modules.

 It is easily understood that such an embodiment makes it possible to construct substantially vertical solar panels of reduced thickness, and on the other hand, to recover, thanks to the lower surface endowed with retro-diffusing properties of the elements 71 inserted, a important part of electromagnetic radiation.

 Of course, the angle of inclination on the one hand of the modules of the photovoltaic cells, on the other hand of the horizontally elongated elements interposed therebetween, must be determined according to the place of installation, and the period of use.

 As an example, modules 1 could be inclined to the vertical by an angle a of the order of 300.

 Of course, the present invention is not limited to the embodiments which have just been described, from which it is possible to envisage numerous variant embodiments without departing from the scope of the present invention.

Claims (10)

 1. Module of photovoltaic cells characterized in that it comprises a bowl (10) generally flat in sheet metal, internally enamelled and of light color, a transparent rigid plate (50) fixed on the bowl at the opening contour of this, to define with the cuvette a sealed chamber, a transparent liquid which fills the chamber formed by the cuvette and the transparent rigid plate, as well as a plurality of photovoltaic cells (30) immersed in the liquid, fixed on the base plane (11) of the bowl (10) and connected to each other by electrical connections (32) including at least two t33) are accessible outside the module.  2. Module of photovoltaic cells according to claim 1, characterized in that the transparent rigid plate (50) is a plate of glass or synthetic material.  3. Module of photovoltaic cells according to one of claims 1 and 2, characterized in that the transparent rigid plate (50) is bonded to the contour of the bowl (10).  4. phatovoltaric cell module according to claim 3, characterized in that the transparent rigid plate (50) is bonded to the bowl (10) using a flexible adhesive (60).  5. Module of photovoltaic cells according to one of claims 1 to 4, characterized in that the photovoltaic cells (30) are bonded to the flat base (11) of the bowl (10).  6. Module of photovoltaic cells according to one of claims 1 to 5, characterized in that the liquid (40) has a high coefficient of thermal conduction.  7. Module of photovoltaic cells according to one of claims 1 to 6, characterized in that the liquid (40) has a low freezing point.  8. Photovoltaic cell module according to one of claims 1 to 7, characterized in that the liquid (40) contains ethylene glycol.  9. Module of photovoltaic cells according to one of claims 1 to 8, characterized in that the liquid (40) contains a compound capable of absorbing electromagnetic radiation whose wavelength is located outside the sensitivity spectrum of the cells photovoltaic (30), and re-emit electromagnetic radiation whose wavelength is closer to the maximum sensitivity of photovoltaic cells (30).  10. Module of photovoltaic cells according to one of claims 1 to 9, characterized in that there is provided at least one orifice (13,14) for the introduction and draining of the liquid (40).  li. Solar panel comprising photo-voltaic cells, characterized in that it comprises a plurality of modules (1) according to claim 1, elongated substantially horizontally and inclined to the vertical (OO), so that the rigid plate transparent (50) is directed upwards, by the fact that the modules (1) are spaced apart, and by the fact that horizontally elongated elements (71), inclined on the vertical symmetrically with respect to the module and whose surface lower is endowed with retro-diffusing properties, are imbricated between the said modules.