ITRM20120114A1 - SWITCHING APPARATUS. - Google Patents

Description

"SWITCHING DEVICE"

DESCRIPTION

The present invention refers to a switching apparatus for controlling and setting the circuit configuration of the panels of a photovoltaic module. A photovoltaic module is generally equipped with a plurality of photovoltaic panels (at most single cells) electrically connected to each other.

It is known that, during use, it is unlikely that all the panels of the module are always irradiated uniformly and with the same intensity with respect to each other. There are a variety of reasons why this doesn't happen.

The non-uniformity of the irradiation of the panels is the factor that most penalizes the producibility of a photovoltaic system.

In fact, as is well known, a series connection of differently irradiated panels enslaves the yield of the entire string to the productivity level of the less illuminated panel. On the other hand, their parallel connection involves the risk of supplying current values higher than their operating currents to the circuits present downstream of the generator.

It therefore becomes important to design the connections of the panels of each module, on the basis of the possible radiation to which they will be subjected during operation.

The proposed invention consists of a new and efficient electrical scheme for reconfiguring the connections of the panels capable of favoring the maximization of the power extracted by a photovoltaic generator in conditions of partial irradiation of its modules.

The main objective of the innovation is the enhancement of the electricity obtainable from a photovoltaic generator in conditions of partial shade. The reuse of all panels guarantees in particular an increase in yield in those plants located in urban environments where the problem of partial irradiation of the panels, due to weather conditions, is further burdened by fixed and prolonged shadows projected on part of the generator from neighboring structures and buildings. These circumstances, in correspondence to which the proposed system shows all its robustness, could be unacceptable for systems characterized by a static part and an adaptive part, as they would severely limit the yield if the shadow falls on the modules of the static part of the system. Some circuit configurations are known which allow a partial modification of the connections between photovoltaic panels.

For example, ES2372518 describes a switching device whose purpose is to reconfigure the connections between the photovoltaic panels of the same module. However, identifying a module with a matrix of panels, the wiring diagram proposed in this document does not allow you to change the number of rows, it is in fact necessary to have at least one panel per row to ensure the continuity of the circuit.

Furthermore, the device of the known art provides for a considerable complexity, since it requires the use of multipolar switches. In particular, as the number of lines on which the panels are to be distributed increases, the use of switches with a number of poles equal to the number of lines desired is required. This obviously makes the expansion of a system of photovoltaic panels controlled by such a device complicated.

A switching device is further known which allows to at least partially obviate the complexity problems described up to now in relation to the known art. This device actually allows a simplification and avoids the use of multipolar switches, however it still has the important disadvantage of allowing a plurality of redundant configurations, thus still maintaining an unnecessarily excessive complexity.

The object of the present invention is to solve the numerous problems still left open by the known art and this is achieved through a switching device as defined in claim 1.

Further characteristics of the present invention are defined in the corresponding dependent claims.

Advantages of the Invention

The present invention, overcoming the aforementioned problems of the known art, entails numerous and evident advantages.

In particular, the present invention makes it possible to set any series / parallel combination (in particular parallel series) of the panels of the photovoltaic module, as a function of the irradiation value of each individual panel. This scheme is in fact able to allow also the two limit configurations in which either all the panels are connected in series (for which there will be a panel for each row) or are all connected in parallel (for which all the panels will be arranged on one line). This allows to avoid the risk of damage to the photovoltaic panels due to the hot-spot phenomenon and allows to achieve the goal of maximizing the output power from the module.

The dynamism of the scheme according to the present invention in fact allows the photovoltaic module to provide the inverter with the best power curves possible under certain shading conditions, overcoming the limits caused in this sense by the use of rigidly symmetrical matrices (i.e. ̈ of matrices in which the number of rows and the number of panels for each row is fixed) or by approaches based on the interconnection between a static part of the system (i.e. between a certain number of modules arranged in a matrix rigid) and a minority of modules available for adaptation.

Brief description of the drawings

The present invention, overcoming the problems of the known art, entails other numerous and evident advantages which, together with the characteristics and methods of use of the present invention, will become evident from the following detailed description of a preferred embodiment thereof, presented by way of example and not. limitative, referring to the figures of the attached drawings, in which:

- figure 1 represents a schematic diagram of a preferred embodiment of a circuit diagram which can be realized by means of a switching apparatus according to the present invention;

Figure 2 shows an exemplary block diagram of an apparatus according to the present invention; And

- Figures 3A to 3E show, by way of example, some possible series / parallel combinations obtainable with an apparatus according to the present invention.

Detailed description of the drawings

The present invention will be described in detail below with reference to the figures indicated above.

Referring first to figure 1, this shows a schematic diagram of a circuit diagram 10 which can be made by means of a switching apparatus according to the present invention for the electrical connection of a photovoltaic module 11 consisting of a plurality of photovoltaic panels Pi.

It is therefore to be understood that the Pinon photovoltaic panels are part of the apparatus according to the present invention.

Naturally, it must be understood that the number n of Pidel module 11 photovoltaic panels is absolutely arbitrary and for this reason it is generically indicated with n. The present invention, its realization and its functioning are in fact independent from the actual value of n and the structure of the apparatus is scalable with respect to this value.

Therefore, in this description, the indication n is to be understood as the number of photovoltaic panels included in the module. For clarity, therefore, in the present description, some elements will be identified in a parametric way, by means of a subscript i or k, to indicate a generic element among the n foreseen. In particular, according to the present invention, a switching apparatus comprises a number equal to n, ie equal to the number of panels provided for the module to be controlled, of pairs of row conductors CRi.

It has already been explained, and it will be even clearer in the following, that the present invention has the objective of making a connection of the photovoltaic panels that make up a module, according to any series / parallel configuration. In other words, in general, the present invention must be able to carry out a series connection of rows of panels connected to each other in parallel. Of course, among the possible combinations there are also the two limit combinations to be considered, ie a single row of n panels in parallel and n rows in series, each comprising a single panel.

According to the present invention, the apparatus further comprises n line switches IRi, arranged in such a way that each of them can realize an electrical continuity between the line conductors of each pair when it is closed.

Advantageously, the IR line switches are single pole switches.

Furthermore, the pairs of line conductors are connected together in series, in such a way as to form, when all the line switches are closed, a single continuous, open conductor, at the ends of which it will be possible to take the energy generated by the photovoltaic module.

Each Picic photovoltaic panel includes two poles, generally indicated as P + and P-, from which it is possible to take the energy generated by the panel.

For each photovoltaic panel Pi, one or more bipolar switches CBi is also provided, each arranged in such a way as to be able to connect each pole of the panel Piad to a respective row conductor CRi one of said pairs of row conductors CRi. Therefore, according to a general embodiment of the present invention, each of the Pipes panels can be connected to one or more of the row conductor pairs CRi.

In particular, according to the preferred embodiment of the present invention, shown in Figure 1, the same number of CB bipolar switches is not provided for all Pidel modulo panels.

According to this scheme, with the index k varying between 1 and n, k bipolar switches are provided for the panel Pk, suitable for connecting the panel Pka k pairs of row conductors.

Moreover, preferably, each Pipot panel can be connected to a single pair of row conductors, by closing only one of the bipolar switches associated with it.

This preferred embodiment provides a triangular array of links, which eliminates redundant links from more generic embodiments.

The following figure 2 shows, by way of example, a block diagram of an apparatus 1 according to the present invention.

In particular, the apparatus 1 comprises a control system 2 of the line switches IRie of the bipolar switches CBi.

To this end, it can be provided that the control takes place through means to command the opening and / or closing of the line switches and / or the bipolar switches according to the irradiation values Vimeasured for each of the photovoltaic panels Pi.

The operation of the switches and commutators, by such control means, can be carried out according to any technique known to date. It does not seem necessary to go into these details which are to be considered within the reach of a technician in the sector.

It is also preferably provided that the control system comprises means for measuring an irradiation value V for each of the panels Pi.

This measure would be made in correspondence with each element considered to be an element to be reconfigured. In fact, in the case of large systems this measurement would be made at the level of a single string, while in the case of small domestic systems this measurement would also be made at the level of the single panel. The measurement systems, which use small hall-effect probes for current measurement and resistive partition systems for voltage measurement, must be connected to the control system either through a traditional wired connection system or through wireless communication. This is in order to update the control system in real time about the irradiation status of the system and allow it to identify the correct reconfiguration strategy.

Therefore, the control system can be equipped with calculation means suitable for calculating a series / parallel configuration of the panels Pi, on said pairs of row conductors CRi, in such a way as to obtain an equalized distribution of the total irradiation value V on all pairs of row conductors.

In this definition, the total irradiation value VRi is to be understood as the sum of the irradiation values measured for each panel of the same row, ie connected to the same pair of row conductors.

By way of example, the calculation means comprise an electronic processor, for example a personal computer or a microcontroller, a PLC or the like, on which runs a program that performs the processing of the input data (the irradiation values) to calculate the optimal series / parallel configuration.

To allow adaptation to any type of requirement, the control system is preferably provided with means for setting one or more configuration parameters, for example through interface tools, such as keyboards, monitors, etc.

By setting some parameters it is in fact possible to limit the possibilities of series / parallel configuration, according to the specific design and use needs of the photovoltaic module.

For example, the configuration parameters that could be set may advantageously include one or more of the following:

- minimum number of line switches to be left open;

- maximum number of line switches to be left open;

- minimum number of panels connected in parallel for each pair of row conductors;

- maximum number of panels connected in parallel for each pair of row conductors.

The following figures from 3A to 3E illustrate by means of an example some reconfiguration modalities possible by means of the present invention.

The example in the figures envisages a photovoltaic module made up of four panels.

By way of example, Figure 3A shows a situation in which the four panels are differently irradiated. On the first two, for example, an irradiation of 100 W / m2 is measured, on the third an irradiation of 800 W / m2 and on the fourth an irradiation of 1000 W / m2.

Figure 3B shows a first configuration obtainable through the selective activation of the line switches and bipolar switches. In particular, it is shown how it is possible to divide the four panels on two lines, putting the first three in parallel on a line and then connecting this line in series with the fourth panel, so as to obtain an equalized distribution on the two lines with a value of total irradiation equal to 1000 W / m2 for each of the two lines.

Figures 3C, 3D and 3E respectively show other configurations that can be reached through the invention, including those limit in which all the panels are on the same row or all the panels are in series with each other, even if less advantageous than the values of irradiation hypothesized in the example.

The present invention has been described up to now with reference to a preferred embodiment thereof. It is to be understood that other embodiments may exist which pertain to the same inventive nucleus, all falling within the scope of the protection of the claims set forth below.

Claims (9)

CLAIMS 1. Switching apparatus (1), for the electrical connection of a predefined number n of photovoltaic panels (Pi) according to any series / parallel configuration, comprising: - n pairs of row conductors (CRi); - n line switches (IRi) arranged in such a way that each of them can realize an electrical continuity between the line conductors (CRi) of each pair when it is closed; said pairs of row conductors (CRi) being connected in series, in such a way as to form, when all said row switches are closed, a single continuous, open conductor; the apparatus also comprising, for each photovoltaic panel (Pi), one or more bipolar switches (CBi), each being able to connect each pole (p +, p-) of the panel (Pi) to a respective row conductor (CRi) ) of one of said pairs of row conductors (CRi), in which the generic k-th photovoltaic panel (Pk) can be connected, through k bipolar switches (CBi), only to k pairs of row conductors (CRi). Switching apparatus according to claim 1, wherein said line switches (IRi) are single pole switches. Switching apparatus according to one of the preceding claims, further comprising a control system (2) of said line switches (IRi) and of said bipolar switches (CBi). Switching apparatus according to claim 3, wherein said control system (2) comprises means for measuring (3) an irradiation value (Vi) for each of the panels (Pi). 5. Switching apparatus according to claim 4, wherein said control system comprises means for controlling (4) the opening and / or closing of said line switches (IRi) and / or said bipolar switches (CBi) in function of said values of irradiation (Vi) measured. Switching apparatus according to claim 4 or 5, wherein said control system comprises means for calculating (6) a series / parallel configuration of panels (Pi) on said pairs of row conductors (CRi), so as to obtaining an equalized distribution of the overall irradiation value (VRi) for each of said row conductor pairs (CRi). Switching apparatus according to one of claims 3 to 6, wherein said control system is such that each panel (Pi) can be connected to a single pair of row conductors (CRi). Switching apparatus according to any one of claims 3 to 7, wherein said control system comprises means for setting (5, 6) one or more configuration parameters, suitable for limiting the possibilities of series / parallel configuration. Switching apparatus according to claim 8, wherein said one or more configuration parameters comprise one or more of the following: - minimum number of line switches (IRi) to be left open; - maximum number of line switches (IRi) to be left open; - minimum number of panels (Pi) connected in parallel for each pair of row conductors (CRi); - maximum number of panels (Pi) connected in parallel for each pair of row conductors (CRi).