WO2011032693A2 - Low-maintenance electronic component for the prevention of reverse currents and for the simultaneous protection from excess currents in photovoltaic systems - Google Patents

Abstract

The invention relates to an electronic component (31, 32) for the prevention of reverse currents and for the protection from excess currents in a photovoltaic system which comprises at least two strands (10, 11) connected in parallel, each of which comprises at least one solar module (4, 8), the electronic component (31, 32) being designed to be connected in series to at least one of the solar modules (4, 8), and the electronic component (31, 32) comprising a series connection of a diode and a fuse. The invention further relates to a photovoltaic system comprising at least two strands (10, 11) connected in parallel, each of which comprises at least one solar module (4, 8), and further comprising an electronic component (31, 32) for the prevention of reverse currents and the protection from excess currents in the photovoltaic system, the electronic component (31, 32) being connected in series to at least one of the solar modules (4, 8) and the electronic component (31, 32) comprising a series connection of a diode and a fuse.

Description

 Low-maintenance electronic component to prevent backflow while protecting against overcurrents in photovoltaic systems

The invention relates to an electronic component for preventing reverse currents and to protect against overcurrents in a photovoltaic system and a photovoltaic system with such an electronic component.

The generation of electricity with the help of photovoltaic systems is gaining more and more importance. In a photovoltaic system, several solar cells are usually connected in series to form a so-called string or string, which convert the received light energy of the sun into electrical energy in the form of direct current. The solar cells of a strand may, for example, be located in a single solar module, but are usually distributed over different solar modules.

The latter is illustrated in Figure 1, which shows a schematic representation of a strand 10 of a photovoltaic system, which has four series-connected solar modules 1 to 4, for example. As indicated by the dots between the solar modules 2 and 3, the string 10 may also include more than four solar modules. As can be seen further in FIG. 1, each of the solar modules 1 to 4 has a multiplicity of solar cells connected in series. For reasons of clarity, only the solar cells 1a to 1h of the first solar module 1 are designated in FIG. The solar cells of the solar modules 1 to 4 generate the direct current Iio by converting light energy.

As a rule, several hundred solar cells are connected in series in a string of a photovoltaic system, so that typically strand voltages of several hundred volts are achieved. In order to achieve higher currents, several strings are connected in parallel in a photovoltaic system, so that the currents generated in the individual strings are summed up to a higher summation current.

This is shown schematically in FIG. 2 by the example of two strands 10, 11. As can be seen in FIG. 2, the current Iio generated in the line 10 and the current In generated in the line 11 are summed in the node 10, 11 common to the summation current Is. In addition to the currents Iio, In, generated in the respective strands, reverse currents in a photovoltaic system can arise, inter alia, when similarly constructed strands 10, 11 are connected in parallel, as in FIG. 2, and are illuminated very differently, as described, for example, in US Pat Sequence of partial

5 shading of the photovoltaic system may be the case. In this case, current that has been generated in one of the strings flows partly into one or more of the further strings connected in parallel, which is or will become from an energy producer to an energy consumer. In FIG. 2, a portion of the current Iio generated in the strand 10 could thus flow into the strand 11 connected in parallel,

3 which can lead to a reduction of the total current Is.

The said return currents in a photovoltaic system thus usually lead to a decrease in the energy production and thus the efficiency of the entire photovoltaic system.

If, in the parallel connection of several strands, the number of well-lit strands is significantly greater than the number of insufficiently lit strands, then in the insufficiently illuminated strands, high reverse currents (overcurrents) may occur, which are traversed by the high reverse current (overcurrent) ) Solar cells can be damaged or even destroyed.

In addition, in the strands of the photovoltaic system to come from defects caused by overcurrents, which can also damage or destroy solar cells.

It is an object of the present invention to provide an electronic component and a photovoltaic system with such an electronic component, with which return currents and overcurrents occurring in the photovoltaic system can be reduced efficiently in a simple manner.

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This object is achieved by an electronic device for preventing reverse currents and to protect against overcurrents in a photovoltaic system comprising at least two parallel strands, each of which has at least one solar module, wherein the electronic component is designed to be in series with at least one the solar modules to be connected, and the electronic component comprises a series connection of a diode and a fuse. The diode is connected in such a way that it is forward-biased for the current generated by the solar module with which it is connected in series, while it is for an oppositely flowing return current, such as for a return current coming from a parallel-connected strand , is poled in the reverse direction. As a result, the diode ensures that the current generated by the solar module is transmitted by it, while an undesirable reverse current is almost completely avoided or at least reduced. By reducing or avoiding the reverse current through the diode (apart from possibly occurring parasitic leakage currents through the diode) also a burnout of the fuse under normal operating conditions as well as in partial shading can be avoided. This avoids localization of the blown fuse and replacement of the blown fuse, so that the electronic component and the photovoltaic system into which the electronic component is inserted become low in maintenance. The fuse ensures that when unexpectedly high currents occur, which can damage or destroy solar cells, the circuit or string containing the fuse is disconnected. The separation of the strand causes no current and thus no overcurrent can flow in the strand, so that damage or destruction of solar cells is prevented.

The electronic component may be connected in such a way with one of the solar modules located in a strand that one end or a beginning of the strand is connected to the electronic component. For example, the electronic component is connected to one end of the strand so as to be serially installed on the positive side of the strand (on the positive-potential side). Alternatively, the beginning of the strand may be connected to the electronic device so as to be serially installed on the negative side of the strand (at the negative-potential side). In these two cases, the electronic component is connected only on one side with a solar module or more solar modules. Alternatively, the electronic component can also be arranged between two solar modules in one strand.

In the electronic component itself, the order of diode and fuse is arbitrary. Consequently, the diode can be arranged in the flow direction of the generated current in front of or behind the fuse. The electronic component can be connected in series with each of the at least two strings connected in parallel. Alternatively, an electronic component may not be provided for each of the strands, so that, for example, only one electronic component is connected to the common node of the at least two parallel-connected strands. Thus, in the case of two strings connected in parallel, a single electronic component can be connected to the common node of the two strings connected in parallel. In this way, more than two, for example four, strings connected in parallel with less than four electronic components, for example with an electronic component arranged at the common node, can be interconnected.

According to a variant embodiment, groups of strings connected in parallel can be formed, which can each be connected to the electrical component via their common end node or starting node. Each of the plurality of groups may comprise two or more strings connected in parallel. In particular, it can be dispensed with according to this training variant thereof, connect the electronic component with each strand of a group in series. Rather, only the common node of each group can be connected to the electronic component. In this way, the number of electronic components used can be reduced while at least reducing the return currents can be achieved.

In a further development, the electronic component may comprise a fuse, but more than one diode, in particular two, three, four or five diodes, which are connected to the fuse. The diodes are connected according to this development so that all the cathodes or all the anodes of the diodes are connected in series to one terminal of the fuse. As a result, maintenance-intensive fuses can be saved and at the same time the diodes minimize the return current.

Typically, voltages between 500 volts and 1000 volts, preferably about 800 volts, are generated along the respective strands. As a result of different irradiation of the strands, however, several hundred volts of voltage difference between two or more strands may occur. Based on these

Voltage differences, a diode would have to be used which can still be operated at the maximum voltage differences occurring by tion strength of the maximum possible in one strand voltage or exceeds this. However, by combining the diode with the fuse in the electronic device, such as a fuse, it is not necessary for the diode to have a maximum withstand voltage equal to the maximum strand voltage. Due to the lower required dielectric strength, low-loss diodes with low forward voltages can be used.

For example, the diode included in the electronic device may be formed as a Shottky diode with a low forward voltage of about 0.4 volts.

The diode may also include or be formed as an active electronic circuit, wherein the active electronic circuit may control the flow of current through the strand having the active electronic circuit or through the strand connected to the active electronic circuit such as a diode. In accordance with this, a diode within the meaning of the invention can be understood to mean not only a common diode, but, for example, an actively controlled metal oxide semiconductor (MOS) transistor, which regulates the current flow like a diode and thus corresponds in its functionality to a diode. This MOS transistor can also be operated in inverse operation (i.e., in reverse current flow between the source and drain terminals of the MOS transistor and normal operation). In this inverse operation of the MOS transistor, it is advantageous that the substrate diode present between the drain and the substrate, which is usually connected to the source, has the desired polarity and does not interfere. By using the actively controlled MOS transistor as a diode line losses can be further reduced.

The combination of the diode and the fuse may be incorporated as the electronic component in a common housing. This housing then preferably has a plug connection which is complementary to a connection cable arranged on the solar module with which the electronic component is to be connected. If solar modules without connection cables are used in the photovoltaic system, the electronic component is preferably installed in a connection cable which has a plug connection at the cable end which is complementary to the connections to the connection box of the solar module with which the electronic component is to be connected. According to a further development of the electronic component, the electronic component may comprise an electronic circuit which can use the voltage drop across the diode occurring due to the current flow in the diode to generate current for supplying further electronic circuits. Alternatively, the electronic circuit may preferably have at least one solar cell which can generate the current for supplying the further electronic circuits.

The electronic circuit may further comprise a communication component that enables communication with other components of the photovoltaic system. In particular, the communication component via an interface allows communication with a monitoring server for monitoring the

Photovoltaic system. Communication with other components, such as the monitoring server, may be wired, for example, over existing power lines, or wireless, such as via a wireless local area network (WLAN) or via Bluetooth.

In addition, the electronic circuit may have a measuring component for determining measured values for the current through the fuse and the diode. The measuring component is preferably connected to the communication component in the electronic circuit, so that the communication component can transmit the measured values for the current determined by the measuring component to the further components of the photovoltaic system, which can then evaluate the measured values obtained.

Instead of the measuring component or in addition to the measuring component, the electronic circuit can have an environmental measuring component for determining measured values for ambient variables of the photovoltaic system. In particular, the ambient temperature and the wind speed around the photovoltaic system can be determined by means of the environmental measurement component. The environmental measurement component is preferably connected to the communication component, so that the communication component can transmit the determined measured values for the ambient variables, such as for the ambient temperature and wind speed, to the further components for evaluation wired or wireless.

According to a development, the electronic circuit may comprise an error detection component which is designed to detect faults in the string into which the electronic component is installed or with which the electronic component is connected to recognize. The detected errors can be transmitted as status messages via the communication component to the other components of the photovoltaic system and evaluated there.

In particular, the electronic circuit includes a fuse component that can detect the absence of or defects in at least one of the solar modules. For example, the fuse component is configured to detect the absence of or faults in solar modules that are in the same string as the electronic component. If faults or defects in one of the solar modules are detected by the fuse component, the fuse component can control the communication component such that no communication via the communication component is possible any more, for example by deactivating the communication component. Only after a reactivation of the communication component, e.g. the defect has been corrected or the faulty solar module has been replaced, a communication via the communication component is again possible. If the communication component of the communication component via the string lines of the solar system takes place, a lack of a module can be detected by the fact that the communication component no longer responds due to the lack of connection to signals that should address the communication component.

Also, the electronic device may include an energy storage device, such as a capacitor, that can store energy and power the components of the electronic circuit, such as the communication component, the measurement component, the environmental component, the fault detection component, and the fuse component. This is particularly advantageous in times when the solar cells do not generate electricity, for example at night.

The above object is also achieved by a photovoltaic system with at least two parallel-connected strands, each of which has at least one solar module, and with an electronic device for preventing reverse currents and to protect against overcurrents in the photovoltaic system, wherein the electronic component in series with at least one of the solar modules is connected and the electronic component comprises a series connection of a diode and a fuse. The photovoltaic system can use any of the previously described Have circuits and each of the previously described embodiments of the electronic component.

The invention is explained below by way of example with reference to the accompanying schematic figures. Show it:

Figure 1 is a schematic representation of a strand of a photovoltaic system;

Figure 2 is a schematic representation of two parallel-connected strands of a photovoltaic system;

FIG. 3 shows a schematic illustration of two parallel-connected strands of a photovoltaic system according to a first embodiment, with electronic components respectively connected in series with the strands, according to a first embodiment; a schematic representation of two parallel-connected strands of a photovoltaic system according to a second embodiment with each connected in series with the strands electronic components according to a second embodiment; a schematic representation of two parallel-connected strand groups of a photovoltaic system according to a third embodiment, each with in series with the strand groups connected electronic components according to the first embodiment; a schematic representation of two parallel-connected strand groups of a photovoltaic system according to a fourth embodiment with each connected in series with the strand groups electronic components according to the first embodiment; a schematic representation of two parallel-connected strands of a photovoltaic system according to a fifth embodiment with strung into the electronic components according to the second embodiment; 8 shows a schematic representation of two parallel-connected strand groups of a photovoltaic system according to a sixth embodiment, each with electronic components connected in series with the strand groups according to a third embodiment; and

FIG. 9 schematically shows a realization of the electronic component according to the third embodiment.

FIG. 3 shows a schematic representation of two parallel-connected strands 10, 11 of a photovoltaic system according to a first embodiment of the present invention, each having electronic components 31, 32 connected in series with the strands 10, 11, according to a first embodiment of the present invention. As shown by way of example in FIG. 3, the first strand 10 has four solar modules 1 to 4, and the second strand 11 has four solar modules 5 to 8 by way of example. As indicated by the dots between the solar modules 2 and 3 and the solar modules 6 and 7 in Figure 3, each of the strands 10, 11 may also have more than four solar modules. However, it is also conceivable that each strand or one of the strands 10, 11 has only one solar module. Furthermore, it can be seen in FIG. 3 that each of the solar modules 1 to 8 comprises a large number of solar cells, of which only four solar cells per solar module 1 to 8 are shown by way of example in FIG. For reasons of clarity, only the solar cells 1a to 1h are designated in FIG. This nomenclature, although not explicitly shown in FIG. 3, also applies to FIG. 3.

Both strands 10, 11 are connected at their end, the end lying at positive potential of the photovoltaic system end, with an electronic component 31, 32 according to a first embodiment of the present invention. In the first embodiment of the electronic component 31, 32, in the direction of the direct current generated in the solar cells Ii ₀ , In, the diode is connected in front of the fuse. Since each of the two strands 10, 11 is connected at its positive end to an electronic component 31, 32 according to the first embodiment, the respectively from the other strand originating return current in each of the two strands 10, 11 is avoided. This is because the diode in the electronic component 31 connected to the first strand 10 only lets through the current Ii ₀ generated in the solar modules 1 to 4 and the diode in the electronic component 32 connected to the second strand 11 only in the solar modules 5 to 8 generated electricity in let through. The occurring in the respective strands 10, 11, - lu ^¬ the currents generated in, in opposite reverse currents are not transmitted by the diodes but locked. This results from the currents generated in the solar modules 1 to 8 Ii ₀ , In, the sum current I _s .

An overcurrent occurring in the strand 10 due to a defective solar cell can be prevented by the fact that the fuse present in the electronic component 31 separates the strand 10 from the remaining circuit of the photovoltaic system. Similarly, the fuse in the electronic device 32 prevents overcurrent in the string 11 by disconnecting the string 11 from the remainder of the photovoltaic array.

According to a second embodiment of the electronic component according to the invention shown in Figure 4, the order of the arrangement of diode and fuse in the electronic components 31, 32 is reversed, so that in the flow direction of the currents generated in the solar modules 1 to 8 Iio, I the fuse before Diode is connected. The electronic components 31, 32 in Figure 4 are connected in the same way as the electronic components 31, 32 in Figure 3 and have the same functionality in that they prevent return currents in the respective strand 10, 11, with which they are connected in series , In this way, a parallel connection of two strings of a photovoltaic system according to a second embodiment is illustrated in FIG.

The interconnections shown in FIGS. 3 and 4 can be expanded, for example, by connecting additional strands in parallel to the strands 10, 11 shown by way of example, and by providing each additional strand with the electronic component 31, 32 at its positive end.

However, if the number of electronic components 31, 32 used is to be reduced, the circuits shown in FIGS. 5 and 6 may be used. These figures show a schematic representation of two parallel-connected strand groups 14, 15 of a photovoltaic system according to a third and a fourth embodiment with in each case in series with the strand groups 14, 15 connected electronic components 31, 32 according to the first embodiment. In both Figures 5 and 6 four strands 10 to 13 are connected in parallel. However, notwithstanding the aforementioned further development of the circuits of FIGS. 3 and 4, the strands 10 to 13 are not connected in series with an associated electronic component 31, 32 in each case. Rather, be in each case two of the strands 10 to 13 are divided into groups of strands 14, 15 of strands 10 to 13 connected in parallel and to each of these strands groups 14, 15 thus formed an electronic component 31, 32 is connected in series.

In this way, as can be seen in Figures 5 and 6, the parallel-connected strands 10, 11 connected to a first strand group 14 and the parallel-connected strands 12, 13 connected to a second strand group 15. The first strand group 14 of parallel-connected strands 10, 11 is connected either at its positive end (FIG. 5) or at its negative end (FIG. 6) to the electronic component 31 according to the first embodiment in series. Similarly, the second strand group 15 of parallel strands 12, 13 connected either at its positive end (Figure 5) or at its negative end (Figure 6) with the electronic component 32 according to the first embodiment in series. This arrangement results in that in the first strand group 14 return streams from the strand group 15 are prevented. At the same time, return streams from the strand 11 contained in the first strand group 14 into the strand 10 and vice versa from the strand 10 into the strand 11 are tolerated. The same applies analogously to the second strand group 15 of strings 12, 13 connected in parallel, in which return currents from the first strand group 14 are prevented by the electronic component 32, but return currents within the strand group 15 are permitted. By the interconnection shown in Figures 5 and 6, the backflow problem is significantly mitigated because backflow only within a strand group 14, 15 but can not occur between the different strand groups 14, 15, since the diode contained in the electronic component 31, 32 streams keeps away from other strand groups.

As shown in FIG. 6, the electronic component according to the invention does not necessarily have to be installed serially at the positive end of the strand or strands. Likewise, the device according to the invention, as shown in Figure 6, be installed at the negative end in series. In this way, the circuits in Figures 3 and 4 can be adjusted.

Figure 7 shows a schematic representation of two parallel-connected strands 10, 11 of a photovoltaic system according to a fifth embodiment with in the strands 10, 11 in electronic components 31, 32 according to the second embodiment. According to the fifth embodiment of the photovoltaic system, two electronic components 31, 32 (which are also covered by the first embodiment) form of the electronic component can be replaced) installed neither at the positive end nor at the negative end of a strand, but built into the strand itself. As can be seen from FIG. 7, a first electronic component 31 is connected between two solar modules 3, 4 of the first strand 10, and a second electronic component 32 is connected between two solar modules 7, 8 of the second strand 11. This interconnection, shown in FIG. 7, also prevents the occurrence of reverse currents in the respective strands 10, 11.

FIG. 8 is a schematic representation of two parallel-connected stringers.

3 groups 14, 15 of a photovoltaic system according to a sixth embodiment with in each case in series with the strand groups 14, 15 connected electronic components 31a, 32a shown according to a third embodiment. As can be seen in FIG. 8, the components 31a, 32a according to the third embodiment have one fuse and two diodes per component. The diodes are for prevention

; of return current in the strands 10, 11, 12, 13 connected in series to each strand 10, 11, 12, 13. However, to protect against overcurrents, it is sufficient to connect only one fuse of each of the strand groups 14, 15 in series. The fuse of the device 31 a can in the event of an overcurrent in the associated strand group 14, this strand group 14 separated from the remaining circuit. Likewise, the

> Securing of the device 32a in the event of an overcurrent in the associated

 Strand group 15, this strand group 15 separate from the rest of the circuit. In this way, the number of maintenance-intensive fuses in each component and in the entire photovoltaic system is reduced, the protection of the strand groups 14, 15 against overflow and the prevention of reverse currents in the strands 10, 11, 12, 13, however, maintained.

Figure 9 shows a realization of the electronic component according to the third embodiment, which is installed in a Y-cable 44. The Y-cable 44 has three connection cables whose respective ends 41, 42, 43 are compatible with the solar modules used in the photovoltaic system (in particular are compatible with MC4). If this implementation according to FIG. 9 is connected in the photovoltaic system according to FIG. 8, the two with the diodes will be connected

connected connection cable via their connectors 42, 43 respectively connected to the complementary connectors of the solar modules 4 and 8 (and accordingly also the solar modules 24 and 28). With the aid of the realization shown in FIG. 1, the electronic component according to the third embodiment, which has a fuse and two diodes, can be installed such that the two connection cables is connected via its plug 42, 43 with the strands 10, 11 of the strand group 14 and the single connection cable via its plug 41 with the strand groups 14, 15 common node (and thus with the common line).

The illustrated embodiments of the electronic component and the schematically shown circuits of a photovoltaic system (which of course are shown only by way of example with two or four strands, but may also have more strings connected in parallel) reduce or avoid by the diode contained in the electronic component return currents in the strands of the photovoltaic system.

If only one fuse were used to secure the strands of the photovoltaic system, the corresponding strand would be cut off if the specified limiting current value were exceeded, so that no damage, for example, to solar cells in the strand could occur. However, while this might solve the overcurrent problem, the backflow problem due to the fuses can not be eliminated. Even if each strand would be individually secured by a fuse, the return current and thus the reduction of energy production in the photovoltaic system could not be avoided, but only the

Damage to the solar cells as a result of unexpectedly high currents through the fuse can be avoided. Furthermore, when using a fuse would be the problem that would have to be detected when burning through the fuse, the burn as well as the blown fuse located and replaced.

If instead of the electronic component only a diode is used, which is poled in the forward direction for the current generated by the solar cells of the associated strand and poled for reverse current in the reverse direction, although the return current could be reduced or avoided by the cells. However, it would not be possible for these diodes to be completely disconnected from the remainder of the circuit to provide protection against overcurrents caused by defects in the strand. However, such a complete separation is indispensable, so that in case of a defect in the circuit of a strand is ensured that there can be no further damage due to excessive currents. However, the electronic component according to the invention and the photovoltaic system according to the invention with the electronic component offer both, a prevention of reverse currents with a simultaneous protection against overcurrents in the photovoltaic system.

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Claims

claims

Anspruch [en] An electronic component (31, 32) for preventing reverse currents and for preventing overcurrents in a photovoltaic system comprising at least two strings (10, 11) connected in parallel, each of which has at least one solar module (4, 8) electronic component (31, 32) is adapted to be connected in series with at least one of the solar modules (4, 8), and the electronic component (31, 32) comprises a series connection of a diode and a fuse.

2. Electronic component (31, 32) for preventing backflow and for protection against overflow in a photovoltaic system according to claim 1,

wherein the diode is formed as a low forward voltage Shottky diode.

3. Electronic component (31, 32) for preventing backflow and for protection against overcurrents in a photovoltaic system according to claim 1 or 2, wherein the fuse is designed as a fuse.

4. An electronic device (31, 32) for preventing reverse currents and for overcurrent protection in a photovoltaic system according to one of claims 1 to 3, wherein the diode comprises an active electronic circuit, which is adapted to the flow of current through which the active electronic Circuit having strand (10, 11) as a diode to control.

5. Electronic component (31, 32) for the prevention of backflow and for protection against overcurrents in a photovoltaic system according to one of claims 1 to 4, wherein the diode and the fuse are installed in a housing which to those on the solar module (4, 8) arranged connecting cables has complementary connectors.

An electronic component (31, 32) for preventing backflow and overcurrent protection in a photovoltaic system according to any one of claims 1 to 4, wherein the diode and fuse are incorporated in a connection cable (44), the plug-in connections (41, 42, 43) which are complementary to the plug-in connections of the junction boxes arranged on the solar modules (4, 8).

7. An electronic device (31, 32) for preventing reverse currents and for overcurrent protection in a photovoltaic system according to any one of claims 1 to 6, wherein the electronic component (31, 32) comprises an electronic circuit adapted to from the voltage drop across the diode occurring due to the current flow in the diode, current for supplying further

to produce electronic circuits.

8. An electronic component (31, 32) for preventing reverse currents and for overcurrent protection in a photovoltaic system according to one of claims 1 to 6, wherein the electronic component (31, 32) comprises an electronic circuit designed to using at least one solar cell to generate electricity for the supply of additional electronic circuits.

9. An electronic component (31, 32) for preventing backflow and for protection against overflow in a photovoltaic system according to claim 7 or 8, wherein the electronic circuit comprises a communication component which is adapted to enable communication with other components of the photovoltaic system, in particular with a monitoring server for monitoring the photovoltaic system, wherein the communication component is wired, in particular via existing power lines, or wirelessly, in particular via a wireless local area network or via Bluetooth, for communication with the other components.

10. Electronic component (31, 32) for preventing backflow and for protection against overflow in a photovoltaic system according to claim 9,

wherein the electronic circuit has a measuring component which is designed to determine measured values for the current through the fuse and the diode, and the communication component is designed to transmit the measured values to the further components.

11. An electronic component (31, 32) for preventing reverse currents and for preventing overcurrents in a photovoltaic system, according to claim 9 or 10, wherein the electronic circuit has an environmental measurement component which is designed to provide measured values for environmental variables, in particular the environment. temperature and wind speed, and the communication component is designed to transmit the measured values to the other components.

12. The electronic component (31, 32) for preventing backflow and overcurrent protection in a photovoltaic system according to one of claims 9 to 11, wherein the electronic circuit has an error detection component adapted to cause errors in the string in which the electronic component (31, 32) is installed or to which the electronic component (31, 32) is connected,

3 and the communication component is designed to transmit the detected errors as status messages to the other components.

13. Electronic component (31, 32) for preventing backflow and for protection against overflow in a photovoltaic system according to one of claims 9

> 12, wherein the electronic circuit has a fuse component adapted to detect the absence of or defects in at least one of the solar modules (4, 8) and to control the communication component so that in the case of missing or defects in at least one of the solar modules (4, 8) no communication via the communication component is possible.

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 14. An electronic component (31, 32) for preventing reverse currents and for overcurrent protection in a photovoltaic system according to one of claims 9 to 13, wherein the electronic component comprises an energy storage device for storing energy for supplying the communication component, the measurement component, the environmental measurement component, the fault detection component and the fuse component having energy.

15. Photovoltaic system with at least two parallel-connected strands (10, 11), each of which has at least one solar module (4, 8), and with an electronic component (31, 32) for preventing backflow and for protection against overcurrents in the photovoltaic system wherein the electronic component (31, 32) is connected in series with at least one of the solar modules (4, 8) and the electronic component (31, 32) comprises a series connection of a diode and a fuse.

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