ITTO20110761A1 - INTERCONNECTION SYSTEM OF MODULES (PANELS) FOR THE PRODUCTION OF ELECTRIC CURRENT ENERGY IN CONTINUOUS CURRENT FROM (BASED ON) CONVERSION OF SOLAR ENERGY, MODULE (PANEL) FOR SUCH SYSTEM, AND METHOD FOR THE MANAGEMENT OF THAT INTERCONNECTION. - Google Patents

Description

DESCRIPTION of the Industrial Invention entitled:

"System of interconnection of modules (panels) for producing direct current electricity from (based on) conversion of solar energy, module (panel) for said system, and method for managing said interconnection"

DESCRIPTION

FIELD OF APPLICATION OF THE INVENTION

The scope of application of the invention relates to systems for the generation, management and use of electrical energy produced by modular direct current electrical energy sources, and in particular a system of interconnection of modules (panels) for producing current electrical energy. continued from (based on) solar energy conversion, module (panel) for said system, and method for managing said interconnection.

STATE OF THE TECHNIQUE

A significant part of the electricity production systems is still made up of large plants, for which the problems concerning the transport and distribution of energy are relevant, in the sense that it is essentially important to minimize the losses along the lines, which are crossed by monodirectional and fairly regular currents. The transport of energy takes place in high voltage along most of the path taken.

In the future, on the other hand, an increasingly significant portion of electricity will be produced in small quantities and therefore will necessarily be fed into the grid in medium or low voltage; it will therefore be very important to minimize the transformations and transport of the energy produced. The ideal condition foresees that there are "energy islands", territorially compact, in which the production and consumption of energy are roughly the same and in which the energy exchanges between islands, and in particular between non-adjacent islands, are reduced as much as possible. .

Therefore, there will be significant amounts of energy produced in small quantities, both due to the fact that small plants will be widespread, and because even the largest plants will be able to produce little energy.

In the following, reference will be made by way of example to electricity produced by photovoltaic conversion systems. In fact, the photovoltaic energy source very effectively exemplifies the problems that will arise with the spread of Renewable Energy Sources (hereinafter also referred to as the acronym FER) and "island" network infrastructures. However, similar problems could be posed in relation to other energy sources that lend themselves to distributed diffusion having operating characteristics similar to photovoltaic plants, such as plants for the production of energy from renewable sources based on the photoelectrochemical conversion of solar energy.

Consequently, many of the conclusions that will be reached will be generalizable and not limited to the case of the presence of electricity produced with photovoltaic systems, but also to these other types of systems, in which non-programmable energy sources are involved, for which it is not It is possible to program a production profile over time, including in the profile, not only the power, but also the current-voltage characteristic.

As is known, solar radiation affects the whole territory, and therefore the exploitation of this radiation to produce electricity is naturally distributed throughout the territory. Furthermore, since the conversion efficiency is not particularly high, an area of considerable size is generally required to produce a significant amount of energy. It is therefore foreseeable that in the future these photovoltaic systems will be distributed over vast territories, as, for example, buildings with suitable roofs to accommodate the installation of such systems are distributed.

Even if weather forecasts will improve further, and therefore it will be easier and easier to predict whether a day will be more or less sunny, it will never be realistically possible to have a forecast of the instantaneous production profile of a photovoltaic system, which is characterized, in the days when there are some clouds in the sky, from enormous variations (even from maximum production to very low or no production) in a few seconds, for example in correspondence with shading due to the fast passage of clouds. Furthermore, even if an instantaneous production profile were predictable, it is not conceivable to expect a consumption profile capable of following the rapid production variations that are typical of a photovoltaic system.

It is therefore clear that the problem of grid balancing is destined to become an increasingly important problem as the share of energy that will generally be produced from non-programmable sources (which are the sources that exploit spontaneous and non-programmable or forced natural phenomena, such as photovoltaics). The concept of grid balancing is an instantaneous concept, i.e. the grid must be balanced moment by moment, and imbalances of the opposite sign, even in rapid sequence, are not compensated for but are added in terms of negative effects on the integrity of the electrical system.

It is known to try to solve the balancing problem by resorting to Energy Storage Systems (hereinafter also indicated with the acronym SAE). These systems are able to absorb and store energy when it is produced, and to make it available to loads when they require it.

Currently, a known type of renewable energy production plant based on photovoltaic energy is composed of a certain number of solar panels connected to an inverter system that converts the energy, intrinsically produced in the form of direct voltage by the panels, into alternating voltage. so that it can be used by local users or sold, again in alternating form, to the public energy distribution network.

The inverter system then receives the energy generated in direct and converts it into alternating by adapting the load seen from the source to the power conditions, in terms of voltage-current pair (I-V), generated by the panels instant by instant. This typically occurs with control systems, for example based on processing carried out according to MPPT (Maximum Power Point Tracking) algorithms. This solution has some drawbacks:

the direct-alternating conversion generates conversion losses;

for certain ranges of current and voltage values, the inverter cannot operate or works with low efficiency so that the energy generated by the RES is lost in whole or in part;

in some particular conditions or times, the network may not be able to absorb the energy generated by the plant and therefore it is forced to interrupt the flow with consequent loss.

The latter occurrence typically occurs in low or insufficient lighting conditions (sunrise, sunset, fog, mist or cloudy sky).

This typical configuration, in which all the energy produced is directly converted into alternating regime, is inefficient when the loads are in continuous regime, as a double conversion becomes necessary to bring it back to continuous regime.

However, this inefficiency has so far been of little importance as the typical loads are in alternating regime and most of the production is fed into the network. This is bound to change in the near future, as grids will not be able to absorb increasing amounts of energy produced in an unscheduled manner without suffering from imbalance problems.

Consequently, SAE energy storage systems must be inserted downstream of the production systems, and these, in the charging phase, are comparable to continuous loads.

However, even in the typical configurations between photovoltaic-inverter system, where all the burden of adaptation between RES and inverter is exerted by the inverter, when the energy production falls below a certain threshold, the electricity to current continuous cannot be converted to alternating regime and is therefore lost.

Even the case of non-uniform illumination of the array of panels causes energy waste, due to the fact that all the panels connected in series (strings of panels) should generate the same current to work with the best efficiency, and all the strings of panels connected together in parallel and connected to the inverter system, should have the same voltage to work with the best efficiency.

According to the known art, an attempt is made to introduce flexibility by introducing flexible configuration techniques. In these cases, however, since the solar panel system is typically organized in strings, when some panels are occasionally shaded, and therefore their production can drastically decrease compared to other unshaded panels, these panels are excluded from production, but normally this exclusion involves the whole string in which these panels are inserted: this measure therefore involves a waste of energy, as other panels of the excluded string would continue to produce energy effectively.

To overcome this kind of losses, a method is known, described in the article "An Adaptive Photovoltaic-Inverter Topology - Mahamoud A. Alahmad et al., University of Nebraska (USA), 2011-IEEE 978-1-61284-220-2 / 11 ". In this article it is proposed to use several inverters with different characteristics that are connected in a programmable way to strings of solar panels in order to expand the range of lighting values for which the system continues to produce energy compared to a photovoltaic system configured in such a way. fixed, as is normally the case. In order to optimize the coupling between the photovoltaic system and the inverter, the length of the strings, which determines the output voltage of the system, is configured in a flexible way, so as to create longer strings when the production is lower, and strings shorter when production is higher. According to this known method, the realization of flexible series-parallel circuits normally makes use of switch arrays, as shown in Fig. 1, which represents a typical case in which the photovoltaic modules can be connected to a "Switching Matrix" switching matrix which allows to modify the various connections.

However, this connection method based on a switch matrix has the disadvantage of requiring a lot of wiring as the individual photovoltaic modules must be provided with cables that cover the distance between themselves and the switching matrix. It is clear that in the case of rather extensive photovoltaic systems such wiring becomes quite expensive, also in terms of cost (it is observed that even the switch arrays are quite complex systems as the size of the array increases). Furthermore, in the solution proposed in the article cited, more inverters are required, and therefore there continue to be the losses introduced in the conversion of the energy from direct to alternating.

In any case, this solution does not solve the problem of compensating for the very rapid imbalances caused by the lighting conditions of the panels so that sudden variations in the supply of electricity at the exit of the system can occur.

SUMMARY OF THE INVENTION

Therefore, the purpose of the present invention is to indicate an interconnection system of modules (panels) for producing direct current electricity from (based on) solar energy conversion, module (panel) for said system, and method for managing said interconnection, designed to solve the above problems.

The object of the present invention is an interconnection system of modules (panels) for producing direct current electricity from (based on) the conversion of solar energy, comprising: two or more of said modules, each module being equipped with a terminal anode and a cathode clamp; at least one power line connected to an anode terminal and a cathode terminal of the system; electrical switching means, at least one at each of said modules, said electrical switching means being configured to connect said anode and / or cathode terminals of one module with anode and / or cathode terminals of another module, or to said power line; or capable of excluding one or more modules from the system; at least an electronic control unit, comprising means for controlling said electrical switch means for determining said connections or exclusions of the modules in the system.

Preferably said system comprises two or more strings, each string comprising one of said electric lines, said at least an electronic control unit comprising means for determining parallel connections between said strings, or for splitting groups of strings in parallel.

A particular object of the present invention is an interconnection system of modules (panels) for producing direct current electricity from (based on) the conversion of solar energy, a module (panel) for said system, and a method for managing said interconnection, as better described in the claims, which form an integral part of the present description.

BRIEF DESCRIPTION OF THE FIGURES

Further objects and advantages of the present invention will become clearer from the following description of preferred embodiments thereof, described purely by way of non-limiting example, with reference to the attached drawings, in which:

Figure 1 shows an example of an interconnection system between photovoltaic panels of a known type;

Figures 2 to 5 show examples of embodiment of an interconnection system between photovoltaic panels in accordance with the present invention;

The same reference numbers and letters in the figures identify the same elements or components.

DETAILED DESCRIPTION OF EXAMPLES OF IMPLEMENTATION Specific reference will be made hereinafter to a non-limiting case of electricity produced by photovoltaic conversion systems. The scope of application of the invention, however, is intended to be extended in any case to plants for the production of energy from renewable sources based on the photo-electrochemical conversion of solar energy. According to a first aspect of the invention, the fact is exploited that RES plants, and in particular those consisting of photovoltaic plants, are characterized by generally being composed of panels or modules which are quite small with respect to the dimensions of the overall plant.

These modules can be connected together in such a way that they can be combined in series and / or in parallel with absolute flexibility. Figure 2 illustrates how such flexibility can be achieved by the very simple actuation of a number of switches.

Figure 2 shows how the single modules MI, Mn of a hypothetical circuit can be organized into strings of variable length by means of simple switches II, .... In "string" is meant a set of modules connected in such a way that can be presented to the outside, all together, with only two clamps. So let's imagine the modules ordered in a row, even if it is clear that in practice this row can be compacted into a sort of serpentine in order to rationally occupy the available space.

Depending on the instantaneous behavior of each module, it is possible to establish the number of consecutive modules to be connected in series, thus determining the desired voltage, which is continuous, at the ends of the circuit, identified as Anode Al (positive terminal) and Cathode CI ( negative terminal). Once the desired number of consecutive modules to be connected in series has been reached, the series connection is interrupted and, by suitably operating the switch as shown in figure 2, it is possible to bring the electrodes of two consecutive panels respectively to the anode A1 and to the cathode CI of the system , and then begin to build a new series (or string) of modules. All the various series (or strings) thus constituted are therefore connected in parallel with each other.

Figure 2 shows in its upper and lower parts only one Anode and one Cathode. However, it is possible to provide a system with 2, 3 or a generic number "N" of Anode-Cathode pairs, organized in such a way that the entire set of modules can be partitioned into 2, 3 or "N" different sub-circuits or sections.

Figures 3.1 and 3.2 below show examples of circuits that can be divided into 2 or 3 divisions.

The case of division into two sections SI and S2, Fig. 3.1, of the energy produced is particularly simple. Sets of strings of modules connected in parallel form a section, SI or S2. Here it is sufficient to place the two input / output terminals of each section at opposite ends of the Anode and Cathode and open the switches appropriately to separate the strings according to the desired proportion.

Even the division into three sections S'1, S'2, S'3 (Fig.3.2) is very simply feasible by opening the Cathode and Anode conductors of the sections in two points instead of just one as in the case of division in two . In this case, another input / output terminal will abut on a new pair of conductors.

From the examples given it is clear how it is possible to generalize the number of divisions, by appropriately organizing the connections of the strings.

The division into several sections of strings can be used, for example, to supply the electricity produced by the various sections to different users.

The wiring diagram shown in Fig. 2 provides for the use of switches positioned between the modules, the wiring is considerably reduced compared to the case of the known art in which the switches are concentrated in a matrix, but the installation of the system with the realization of the related links can be further simplified.

In fact, to create the diagram shown in Fig. 2, it is possible to proceed in an extremely simple way by positioning the switches in correspondence with the electrodes of each module or photovoltaic panel, thus integrating them into the panel itself.

As shown in Fig. 4, it is sufficient that each single module N-1, N, N + 1, includes a pair of simple two-position switches 141, 142, and that it has three input terminals MI and three output terminals MU (in the figure those of form N) are identified. This feature is particularly advantageous in the installation of large photovoltaic systems, which occupy very large areas and for which the simplicity of installation and maintenance is a relevant factor, and therefore the possibility that the necessary switches are integrated into the module itself (without the need for install them separately) is undoubtedly interesting.

It is therefore sufficient to lay the photovoltaic system by connecting the three output terminals of each panel with the three input terminals of the next panel with a three-wire cable.

The three wires respectively represent the "anode line" A4, the "cathode line" C4, and the "string line" S4. The "string line" S4 is used to connect the anode of a panel with the cathode of the adjacent panel if the two panels are to be connected in series. The panels can also be connected all in parallel, closing the anode of each panel on the anode line A4 and the cathode of each panel on the cathode line C4. The typical case, however, requires series circuits to be connected to each other in parallel . It is clear that the circuits to be connected in parallel (which in the case in question behave as generators) must have their point of maximum efficiency all at the same voltage, in order to limit the occurrence of unwanted currents. Normally, therefore, when it comes to connecting modules that are all identical to each other, it will be necessary to configure series circuits consisting of an equal number of modules, to then connect all these series circuits, to each other, in parallel.

It is obviously possible the case of modules that are different from each other, for example illuminated in a heterogeneous way, such as solar panels that for aesthetic reasons are mounted with different inclinations to follow the surface of a building, or even of a different type of source use. energy ,. Their mutual connection, for example in parallel, will be more complex, but still possible, having to search for configurations in which all the circuits connected in parallel have an optimal (or in any case acceptable) working point at the same voltage.

Therefore the cathode of each panel must be connected either with the anode of the adjacent panel through the "string line" S4, if to be connected in series, or with the "cathode line" S4 if this panel constitutes the negative end of the string ; while the anode of each panel must be connected either with the cathode of the adjacent panel, if to be connected in series, or with the "anode line" A4 if this panel constitutes the positive end of the string.

As shown in Figure 5, by slightly complicating the contact system, and by adding a switch, it is also possible to exclude a single panel.

The anode 151 and cathode 153 switches of a panel can also be placed in a third position (in addition to those provided on the basis of what is described in relation to fig. 4) in which they do not make contact with any line: in this case the string line S5 must be closed with a suitable switch 152. Thus, by positioning the switches, a panel is excluded.

The known methods with which a panel is excluded (when for example shaded and / or damaged), would not allow to restore the optimal string length, and therefore, such situations are managed in the known art by excluding an entire string.

The control of the switches can be remotely controlled and managed by a control system at the level of the "energy district" to which the plant is located. The operation of the switches can be simply carried out with an electric command carried on the same line of transfer of the electric energy (for example on the anode and cathode lines) with "Power-Lines" techniques known per se. Note that the command to be sent to each switch is, in the simplest case, one bit.

Compared to traditional "Power Line" applications in which data is transferred on cables in which there is an alternating energy transmission, this case appears simpler as the energy transmission regime is continuous, and therefore it is very easily separable from any carrier, even at a relatively low frequency on which to transmit data. In any case, one of the numerous standards already defined for this kind of application can certainly be used for this purpose. As an example, we cite the IEEE P1901 standards, or those defined by industrial alliances such as the "Universal Powerline Association" or the "HomePlug Powerline Alliance".

Even if the transmission needs of this application are extremely reduced, and therefore there are certainly no problems in using the "Conveyed Waves" technique, it is possible to use an additional device aimed at further reducing the disturbances. Since the activation of the switches is not an operation to be carried out continuously and at high frequencies, it is possible to transmit all the commands to all the switches, without them switching immediately after receiving the command, and then switching with a predetermined delay, or upon receipt of a "trigger" signal. In this way it is avoided that, due to the commutation of the first switches, disturbance transients are generated which could hinder the transmission of the commands for the last switches.

Given the simplicity of the solution, it is possible to integrate these switches into the structure of the panel itself during the construction phase, with marginal additional costs. In this way it is possible to produce panels that can be connected very simply and configurable in a very flexible way in series-parallel combinations.

In this case the "cathode line" and "the anode line" pass through the "Connection system" of each module, and are therefore also easily interruptible and therefore suitable for making the system partitions described above.

It is clear that for partitions higher than order two, it is necessary to pass further pairs of anode / cathode lines as explained above. It is therefore clear that, if the anode and cathode lines are to be integrated into the structure of the modules (for example to avoid the laying of external wiring), these lines (although they can always be integrated into the structure) must be two-row in the case we want to allow tri-partitions, realizing the wiring diagram shown in figure 3.2. Larger partition orders will require the anode and cathode lines to be made with increasing numbers of conductor lines). Variants that aim at further savings in wiring are possible by positioning the triplets of input and output terminals in an appropriate way (for example on opposite sides of the panel). It is also possible to provide for the presence in the panel of complementary interlocking plugs or sockets which do not need any external wiring and which also serve to strengthen the mechanical coupling between the panels of the photovoltaic grid.

The switches can also be configured in such a way as to make it possible to remove the panel, in case of breakdown, repair, replacement, for example. For example, it is possible to equip the panel with input and output connectors, which connect the cathode, anode and string lines to the switches. In the case of integration of the switches in the panel, the connectors include connections such that, in case of removal of the panel, they short-circuit the string line and open the connections to the anode and cathode lines. Or in the case of switches external to the panel, it is sufficient to operate the switches as described above, and disconnect the panel connectors.

The realization of said circuit variants is within the reach of the person skilled in the art.

In general it can be stated that, given a set of photovoltaic panels, it is possible to organize them by connecting them flexibly in order to have a predetermined number of outputs on which to divide the generated or absorbed power by controlling current and voltage, since this control can be carried out with precision. given by the current and voltage characteristics of the individual generating elements.

It has also been seen how, by applying the flexible configuration techniques of the strings mentioned above, it is possible that even a classic RES, such as a photovoltaic system, can be configured in such a way as to present a controllable voltage at the output, depending on the accuracy of the voltage d output from the working voltage of the single panel under certain temperature and irradiation conditions, also contributing to optimally solving the above-mentioned energy balancing problems.

The control system of the present invention can be advantageously implemented by means of a computer program which comprises coding means for carrying out one or more steps of the method, when this program is executed on a computer. Therefore, it is intended that the scope of protection extends to said computer program and further to computer readable means comprising a recorded message, said computer readable means comprising program coding means for carrying out one or more steps of the method. , when said program is run on a computer.

Implementation variations to the described non-limiting examples are possible, without however departing from the scope of protection of the present invention, including all the equivalent embodiments for a person skilled in the art.

The advantages deriving from the application of the present invention have already been described above.

From the above description the person skilled in the art is able to realize the object of the invention without introducing further construction details.

Claims (12)

CLAIMS 1. System for the interconnection of modules (or panels) for producing direct current electricity from (based on) solar energy conversion, comprising: - two or more of said modules, each module being equipped with an anode clamp and a cathode clamp; - at least one electrical line connected to an anode terminal and a cathode terminal of the system; - electrical switching means, at least one at each of said modules, said electrical switching means being configured so as to connect said anode and / or cathode terminals of one module with anode and / or cathode terminals of another module, or to said electric line, or able to exclude one or more modules from the system; at least an electronic control unit, comprising means for controlling said electrical switch means for determining said connections or exclusions of the modules in the system. 2. System as in claim 1, comprising two or more strings, each string comprising one of said electric lines, said at least one electronic control unit comprising means for determining parallel connections between said strings, or for splitting groups of strings in parallel. 3. System as in claim 1 or 2, in which said at least one electric line is further equipped with a string line, and in which said switch means are configured so as to connect the corresponding panel to said string line to make a connection series with at least one other panel, upon command of said at least one electronic control unit. 4. System as in claim 3, wherein each of said two or more modules is equipped with at least one electrical input and at least one electrical output, and wherein said switch means comprise at least one input switch and at least one output switch, said input and output switches being configured in such a way as to connect said electrical line to said electrical input and said electrical output respectively, upon command of said at least one electronic control unit. 5. System as in claim 4, wherein said switch means comprise at least a third switch shaped in such a way as to close said string line when said input and output switches of the corresponding module are open, excluding the corresponding module, otherwise to open said string line, upon command of said at least one electronic control unit. 6. System as in any one of the preceding claims, in which said electrical switching means are integral with the corresponding module. 7. System as in any one of the preceding claims, wherein said switch means are remotely controlled by said at least one electronic control unit through said at least one electric line. 8. Module (panel) for producing direct current electricity from (based on) conversion of solar energy, configured in such a way as to be used in a system as in any one of the preceding claims. 9. Module (panel) for producing electrical energy in direct current as in claim 8, comprising inside said electrical switch means. 10. Module (panel) for producing electric energy in direct current as in claim 8, comprising connection means with said corresponding electric switch means. 11. Method for managing the interconnection of modules (panels) of electricity production from (based on) conversion of solar energy, in a system as in any one of claims 1 to 7, comprising the interconnection steps of each of said modules with other modules, and / or exclusion of one or more of said modules, by actuating said switch means, by means of said at least one electronic control unit. Method for managing the interconnection of modules (panels) for producing electricity from (based on) conversion of solar energy, in a system as in any one of claims 2 to 7, comprising the steps of: interconnection of each of said modules with other modules, and / or exclusion of one or more of said modules of a string; and / or interconnection of said strings in parallel and / or sectioning of groups of strings; by actuating said switch means by means of said at least one electronic control unit.