Abstract:
In an apparatus for shading surfaces, in particular for shading spaces which can be negotiated on foot, or the like, comprising at least a roof sheathing which is stretched on supports or the like carrier elements at a spacing relative to the surface to be shaded, or a corresponding cable netting assembly, as a carrier assembly, on the outside of which are provided photovoltaic elements, the photovoltaic element or solar module is attached to the carrier assembly by intermediate elements with which distortion phenomena of the carrier assembly, which are caused by stretching, can be carried, and external forces can be transmitted to the carrier assembly. In addition a plurality of photovoltaic elements or solar modules of approximately the same orientation are to be connected in series and respective region and the latter are determined by the connected to a regulating system, wherein the solar modules of approximately the same orientation are preferably associated with a respective region and the latter are determined by the direction of incidence of the sunlight to be received, in dependence on the position of the sun.

Description:
This is a continuation, of application Ser. No. 07/813,859, filed Dec. 26, 1991, now abandoned. 
    
    
     BACKGROUND OF THE INVENTION 
     The invention relates to an apparatus for shading surfaces or areas, in particular for shading spaces which can be negotiated on foot, or the like, comprising at least a roof sheathing which is stretched on supports or the like carrier elements at a spacing relative to the surface to be shaded, or a corresponding cable netting assembly, as a carrier assembly, on the outside of which are provided photovoltaic elements. 
     Such an apparatus with silicon crystals which are fixed on the roof sheathing or the cable netting assembly and which are possibly movable relative to each other is described for example in German laid-open application (DE-OS) No 34 27 574. The term photovoltaic elements means, for example, solar cells with a semiconductor plate which in principle is of a double layer configuration, namely an upper negatively doped layer (for example silicon with phosphorus atoms) and a lower positively doped layer (boron atoms). A voltage occurs at an electrical barrier which is provided between the layers, direct current can be taken off directly by way of metal contacts, and can then be adapted to the current mains by inverters. For that reason such photovoltaic elements are also connected directly to current lines. 
     In accordance with German laid-open application (DE-OS) No 31 42 129, a photovoltaic solar module is strengthened by a galvanized iron wire mesh or gauze which carries a layer of lacquer and is connected to the plastic material enclosing the solar cell, with the interposition of a multi-layer foil as a vapor diffusion barrier. A glass cloth and the electrical lines can extend in the plastic material. Outside the region of its solar cell, which is backed by stiff material, that solar module is capable of being adapted to curved rigid surfaces such as uneven ground, motor vehicle roofs, rock faces, house fronts or the like, and such adaptation to the curved configuration therefore occurs, in such a way as to define the appropriate shape, on a single occasion, namely when the assembly is fitted in position. For, movable non-rigid curved surfaces, solar modules of that kind are just as unsuitable as photovoltaic layers of amorphous silicon or of cadmium derivatives, in accordance with U.S. Pat. No. 3,411,050. 
     In accordance with German laid-open application (DE-OS) No 34 27 574, those elements which are combined together in solar modules are applied to vibrating or oscillating roofing systems of large area. The particular circumstances of such structures which are referred to as `lightweight areal load-bearing assemblies` give rise to specific requirements in regard to fixing of the solar modules. The following limit values which are governed by snow and wind loading are specified by the specification IEC 504 from the Commission of the European Community, in respect of upstanding roof surfaces which are suitable for the use of solar modules: 
     Suction forces 2400N/m 2; 
     Pressure forces 5400N/m 2; 
     Shearing forces at 60° C.--angle of pitch 5000N/m 2. 
     Membranes of mesh-like or netting-like fabrics or cable netting assemblies as represents, for example, the roofing of the Olympic Stadium in Munich are usually fitted in a point-like fashion on steel pylons or towers and stretched by means of what are known as bracing riggings to provide cross-sectionally curved, synclastic or anticlastic surfaces. In spite of the prestressing forces applied to them, they experience further slight stretching movements under the effect of snow and wind loadings and thus perform what might be called a breathing motion. The following conditions can apply regarding the stretch effects that occur: 
     
         ______________________________________*Membrane carrier assemblies:            in the warp direction 1-3%;            in the weft direction 1-5%;            angular displacement up to 10            degrees;**Cable netting carrier            Stretch effects up to 1%;assemblies       angular displacement up to 10%.______________________________________ 
    
     That means that rigid solar modules which are fitted on lightweight areal carrier assemblies must be provided with a fixing mode which can permit the described movements. 
     In consideration of those factors, the inventors set themselves the aim of so improving an apparatus of the kind discussed above that the photovoltaic solar modules are secured in relation to the above-indicated forces, on the one hand, but on the other hand they are also capable of accommodating the displacements caused by the suspension configuration. 
     SUMMARY OF THE INVENTION 
     In accordance with the invention, rigid but also flexible photovoltaic elements are to be permanently applied to lightweight areal carrier assemblies of large area and in that respect the movements of the substructure can be compensated by a specific fixing mode in order substantially to broaden the range of uses of lightweight areal carrier assemblies. In the ideal situation the module passes forces into the membrane, without themselves being loaded by membrane deformation, that is to say, optimization is by way of a minimization in the forces applied to the photovoltaic modules by the suspension assembly. 
     The invention therefore provides for fixing of photovoltaic solar modules on lightweight areal carrier assemblies, which can accommodate the stretching effects of the carrier assemblies but which at the same time passes the snow and wind forces of the applied solar modules to the carrier assembly. For that purpose, cast on to the rear side of the respective module is a soft plastic base or support of adequate diameter, whose Shore hardness is preferably between 20 and 30 Shore A when the module is of a size measuring, for example, 500×1000 mm. It is not possible here to use series screwing means for the solar modules in the edge region of the module frame as, when employing a very dense arrangement, buffers or fixing means would mutually impede each other or have to be arranged in mutually displaced relationship. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     Further advantages, features and details of the invention will be apparent from the following description of preferred embodiments and with reference to the drawings in which: 
     FIGS. 1 through 4 show four graphs with different characteristics; 
     FIG. 5 is a plan view of a cable netting arrangement as a roof surface with solar modules arranged thereon, in four groups; 
     FIG. 6 is a side view of a roof sheathing which is erected in the form of an arcade of wave-like configuration; 
     FIG. 7 is a plan view of FIG. 6 with solar modules disposed on the roof sheathing, in three groups; 
     FIG. 8 is a side view of FIGS. 6 and 7 (turned through 90°); 
     FIGS. 9 and 10 are sectional views on an enlarged scale of details from cable netting assemblies, with a part of a solar module; 
     FIG. 11 is a sectional view of an enlarged scale of a detail from a roof sheathing; 
     FIG. 12 is a plan view of a solar module; 
     FIG. 13 is a view in section through a part of a roof sheathing; and 
     FIG. 14 is a plan view of an arrangement of two solar modules. 
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     In accordance with the invention, buffers of fixing means or supports are screwed on to cable netting assembly nodes of junctions or a large-area cable netting assembly or are connected to a membrane which is stretched over a large area. 
     It has been found advantageous for what are known as sliding clamps to be arranged on the standard frames of the solar modules, and for one or two of the fixings each to be in the form of a rigid hard connection in order in that way, by virtue of the combination of a fixed point and a plurality of sliding locations, to compensate for the movement of the sub-structure relative to the solar module by way of the other sliding clamps. 
     In an advantageous configuration, it is possible to use a three-point fixing in which a rigid plate which is glued in position, on the rear side of the module, is disposed in opposite relationship to two buffers or two sliding clamps. By virtue of the omission of a fourth fixing point, there is no longer any need for a degree of freedom in the fixings which permit movements; it is only when a four-point mounting system is used that compensation in respect of height is required, for example by means of a sliding clamp. 
     In relation to solar modules of the order of magnitude of about 500×1000 mm, a two-point fixing has proved its worth, with which the solar module is secured on cable netting nodes or junctions or on a weft thread or yarn of a membrane-type carrier assembly; therefore, there is no longer any need to provide for compensation for movements, in relation to relatively rigid sub-structures. The movements which occur here in the region of the solar modules are minimal. 
     Bars may serve for fixing the solar module to cable netting assembly nodes or junctions, in which case one of the fixings is rigid and the other permits compensating movements. 
     When using membranes which are stretched over a large area, disk means are used for transmission of the fixing forces, for example with flat metal or plastic disk members with a corresponding screw means, which clamp the membrane and thus prevent a stamped hole from tearing out. 
     The disk means or clamping surfaces advantageously have rough surface structures which increase the amount of friction. They may also be plates of a roof-shaped configuration, with which the membrane is clamped in the edge region of the plate. 
     In accordance with a further feature of the invention, a groove and tongue may be provided in the edge region of the plates in order also in that way to provide for clamping of the membrane in the edge region. It is also advantageous to insert O-rings into corresponding grooves in the edge region of the plates in order to provide for improved clamping of the membrane. 
     By virtue of the predetermined configuration of the solar modules, they can be positioned on cable netting assemblies or tent membranes, not in one plane. That involves differences in orientation, whereby the solar modules of the installation are irradiated to different degrees of intensity. In accordance with the invention, the output voltage is now increased by a series connection of a plurality of solar modules which as far as possible are directed in the same direction, in geographical terms. In order to make optimum use of a solar generator, the working point must always be at what is known as the Maximum Power Point (MPP). 
     In addition, there is the danger that the regulating system senses the characteristic in the region of another maximum and does not reach the MPP-point with the maximum power level. That is prevented by the choice in accordance with the invention of a low installation voltage. 
     In accordance with the teaching of the invention, in a photovoltaic installation, solar modules of approximately the same orientation are connected together to form lines. In addition the installation is divided into regions and each region has its own MPP-regulator associated therewith. In that way the optimum working point for each region is set. 
     By virtue of the spatially curved movable carrier surface being divided into regions, the entire installation can be adapted to the movement of the sun; in the morning the region which is directed towards the East operates at the optimum working point, during the midday period the central region is afforded optimum irradiation while in the afternoon it is the region which is towards the West which supplies the greatest power. None of those regions is influenced by the others. 
     The output voltages of the individual MPP-regulators can be fixed to a value and thus feed a common load or consumer or battery storage device. A conventional MPP-regulator comprises a plurality of power portions. Therefore only additional regulating units would be necessary. 
     When partial shading effects occur (due to trees, buildings etc), only the relevant region would be influenced; the other regions continue to operate at the MPP-point and produce the maximum power. 
     It has been found in accordance with the invention that such an installation with solar modules which are oriented in different fashions can be considered to be optimized when 
     the number of series-connected solar modules is kept as low as possible; 
     the installation is divided into small parallel connected regions which take account of the path of movement of the sun; and 
     those parallel-connected regions are more substantially optimized by MPP-regulating systems for each region. 
     Overall, the foregoing teaching considerably improves the economy of photovoltaic installations; it is determined not only by the solar cells and secondary components of the electrical installation, but also by the support or suspension means for the solar modules. The support or suspension means can constitute up to 30% of the overall costs of a photovoltaic installation. The solar modules which are applied in cable netting assemblies can in themselves be regarded as inexpensive solar module suspension means. Furthermore, solar cells which are already connected to form modules and encapsulated can be mounted in position with the fixing systems according to the invention. 
     The solar modules are slightly flexibly suspended so that high-frequency vibrations or oscillations as can occur when using rigid fixings on frame structures of larger sizes are eliminated. The specific acceleration forces which arise out of the first derivative of the oscillation frequency are thus reduced by the factor 1/Ω and are further attenuated by the solar modules. 
     FIG. 1 shows, in a planar co-ordinate system with the ordinate I (=electrical current strength) and the abscissa U (=electrical voltage) the overall characteristic of a group of uniformly directed solar modules. Reference M identifies what is known as the Maximum Power Point (=MPP). 
     FIG. 2 plots in relation to the electrical voltage U the power P for uniformly directed solar modules, with the point M at the maximum of the curve; with optimum utilization of the solar generator, that is the position of the working point for the adjustable solar modules. For that purpose, a regulating system (not shown) of an MPP-regulator senses the characteristic of the solar generator. The power is calculated from the respective current and voltage values. If the power is greater at the next point sensed, the sensing direction is maintained; if it is lower, sensing is effected in the opposite direction and in that way the MPP-point is found and retained. 
     The overall characteristic as shown in FIG. 1, for solar modules directed in different ways, is shown in FIG. 3; in this case the overall characteristic is deformed. At the MPP-point of that interconnection arrangement the power is lower than with solar modules which are uniformly directed, as is shown by the power curve in FIG. 4. 
     In order to produce characteristics as shown in FIGS. 1 and 2, solar modules 20 are fixed to cable netting nodes or junctions as indicated at 16, on a cable netting assembly 10 which is erected in a curved configuration between two high points 12, a high point 13 at a greater spacing from the ground, and two low points 14, as shown in FIG. 5. The position of the cable netting nodes or junctions 16, of which only a few can be seen from FIG. 5, is determined by internal cables 18 and 19 which cross within edge cables 17. 
     The solar modules 20 are respectively combined together into regions or areas indicated at 20 a  to 20 d  ; the central region 20 a , for a large part also the region 20 b , faces towards the zenith, and thus receives, in particular, midday sun. In contrast, the regions 20 c  and 20 d , respectively, are here more associated with the East and the West, respectively, and therefore receive morning and evening sun, respectively. The solar modules 20&#39; b , 20&#39; c , 20&#39; d  which are adjacent to the edge cables 17 between the tensioning points 13 and 14 are connected by means of central connecting members 21 to the cable netting nodes or junctions 16, while the other solar modules 20 a  through 20 d  are respectively associated with a mesh area which is defined by four cable netting nodes or junctions 16, that is to say, the narrow sides of their module frames (not shown in FIG. 5) here extend above the internal cables 19 and each lie with their longitudinal axis on a respective cable netting node or junction 16. 
     The drawing also does not show current lines connecting at least four respective solar modules 20 of a region together, and the connections thereof to a current receiving means. 
     Both in this installation and also in a further installation as shown in FIGS. 6 through 8, the working voltage is fixed at 48 V, for which purpose there are always four solar modules 20 connected in series. 
     A structure referred to as a wave- like arcade, as shown in FIGS. 6 through 8, comprises a carrier structure 26 which includes vertical supports 22 and arcuate stretcher members 23 on horizontal bearers 24, and a roof sheathing 28 which is stretched over the structure 26 and which forms a ridge 29 of a catenary curve-like configuration. Solar modules 30 are arranged in three groups 30 a , 30 b , 30 c  on the roof sheathing 28, on the side of the arcuate stretcher member 23 which is directed towards the South; of the groups of solar modules 30, the middle group 30 b  receives solar energy, in particular, at midday while the flanking groups 30 a  and 30 c  receive solar energy prior to midday and after midday. 
     The solar module 20&#39; shown in FIG. 9 can be fixed to the cable netting assembly 10, for example, by a plastic base or support 32 which is screwed to sleeves 33 at the cable netting node or junction 16, and acts as a buffer. Its Shore hardness is between about 20 and 30 (Shore A), for example, for a solar module 20 of a length n of 1000 mm and a width b of 500 mm, as shown in FIG. 12. 
     FIG. 10 shows a solar module 20&#39; on a cable 11 of a cable netting assembly 10; it is fixed to the cable 11 by a cable clamp 46 with clamping plates 47 which are disposed on both sides of the cable 11 and which are connected by screws 38. The clamping connection 11/46 slides, as from a defined force acting on the solar module 20&#39;. 
     In order to be able to carry shearing forces, one of the fixing points should be rigid whereas the other fixing points carry only pressure or suction forces. The combination of fixed points with sliding regions, at cable or sliding clamps 46, provides for compensation in respect of the movements of the sub-structure 10, 28 with respect to the solar module 20, 30. 
     The solar module 30 shown in FIG. 11 is fixed with the interposition of the above-described plastic base or support 32 on a membrane-like roof sheathing 28 by means of screws 38 which pass through stamped-out holes 40 and support plates 39 and can be tightened by way of a nut 41. 
     In that way a module frame 34 of the solar module 30 which is shown in plan view in FIG. 12 can be fixedly connected to the supporting roof sheathing 28 (not shown here) at the locations 35 whereas at locations36 it can be mounted slidably by virtue of sliding clamps. 
     FIG. 13 also shows in diagrammatic form the manner of fixing a solar module 30 to the roof sheathing 28 by means of a screw 38; the roof sheathing 28 is held around the hole 40 through which the screw 38 passes, on both sides, by clamping plates 42 which are disposed between the nuts 41 and which have grooves 43 receiving O-rings 44. 
     Finally, FIG. 14 shows two adjacent solar modules 30, 30&#39; of which the left-hand one is provided with a fixing screw 38 and the right-hand one is provided with a sliding clamp 49 having slots 48.