ITTO20110616A1 - SYSTEM FOR SAFETY SOLAR SYSTEMS. - Google Patents

Description

TITLE: SYSTEM FOR SECURING SOLAR SYSTEMS

------- The present invention refers to a system for securing one or more solar systems, preferably photovoltaic ones, suitable for electrically dissecting portions of said system, in order to obtain a safety low voltage perfectly compatible with electrical safety standards.

In the photovoltaic electricity generation sector, it is customary to have photovoltaic modules or panels of relatively low voltage, which are connected in series, obtaining strings. Typically the voltage of a single module or panel is low enough to be considered safe. In fact, each photovoltaic module complies with safety regulations by generating, in use, a voltage at its ends normally lower than 40Vdc.

The series connection of the various modules in strings means that high voltages can be reached at the ends of said string. The values of said high voltages are directly proportional to the number of panels connected in series. For example, the construction of a typical photovoltaic system, in the home, of 3kWp involves the connection, in series, of about twelve photovoltaic modules, creating a string which, in use, will have a voltage of about 420Vdc at its ends.

In traditional systems, when the string is irradiated by the sun's rays, there will always be a high voltage at the ends of said string, without the possibility of safely disabling the generation of the voltage itself, for example in case of danger.

The electrical safety directives, to date, provide for the insertion of a direct current switch â € œDCâ € between the photovoltaic system, consisting of these modules, and the input of an inverter for the generation of alternating voltage , included in photovoltaic systems. This solution is only suitable for securing the inverter, but leaves the photovoltaic system, in use, live.

In the event of a daytime fire in a building equipped with a photovoltaic system, even though the mains power supply is disconnected and the inverter has been made safe, said system will have a high voltage at its ends. In fact, this voltage is potentially dangerous for fire extinguishing workers since, for example, it can generate a current conducted through water, poured to put out the fire itself.

Even in the case of access to the photovoltaic system, for maintenance, by an operator, it is necessary to secure the system itself, in order to avoid that, due to accidental contact with the system, the operator may be subjected to a voltage potentially dangerous for health.

A safety system is known to isolate the photovoltaic system at module level. This system includes a control unit to which all the panels or modules included in the system are electrically connected.

This solution, for systems with a number of modules higher than ten, it is necessary to lay a high number of cables. This solution generates a bundle of large cables that is difficult to handle and to lay. In addition, the connection cable of each single panel to said control unit is, on average, of considerable length, thus increasing the cost of building the system. In fact, said connection cable is expensive as it is made with low resistance alloys, guaranteeing correct coupling with the panel.

Switch systems suitable for sectioning a circuit are also known. These systems include semiconductor-type switches, which interrupt or at least reduce the flow of a current inside said circuit, without however guaranteeing galvanic isolation of the contacts; therefore, said type of switches cannot be applied to safety systems.

It is also known the use of relays in safety systems as they guarantee galvanic isolation between the contacts. To ensure the opening of an electrical load in â € œDCâ €, these relays are made with oversized contacts, therefore expensive, and with excitation coils with high consumption.

The present invention aims to solve the aforementioned problems by creating a system for the safety of photovoltaic systems comprising at least one central unit and at least one peripheral unit, in such a way as to allow the safety of photovoltaic systems, even of large dimensions, by sectioning at least one string included in said system at the level of the individual modules or panels included in said string.

An aspect of the present invention relates to a system for securing photovoltaic plants with the characteristics of the attached independent claim 1.

The accessory characteristics are reported in the attached dependent claims.

The characteristics and advantages of the system, according to the present invention, will be better clear and evident from the description of different embodiments of the system, and from the attached figures which respectively illustrate:

â € ¢ Figure 1 shows a block diagram of the system according to the present invention;

â € ¢ Figure 2 shows an embodiment of the electrical diagram of the system of Figure 1;

â € ¢ Figure 3 shows a further embodiment of the general electrical diagram of the system of Figure 1;

â € ¢ Figure 4 shows, in detail, the wiring diagram of Figure 3.

With reference to the aforementioned figures, the safety system, according to the present invention, can be applied to one or more solar systems â € œIâ € for the generation of electricity, each comprising a plurality of modules or solar panels â € œPâ € which, in use, are electrically connected in one or more series called â € œSâ € strings.

Said system comprises at least one central unit 3 and at least one peripheral unit 4.

Said at least one central unit 3 comprises at least one control unit 32, and is electrically connected to one or more â € œSâ € strings, and to a power source 2 suitable for powering said safety system.

Said at least one peripheral unit 4 is electrically connected to at least one string â € œSâ € and with said central unit 3, and includes a plurality of switches (43, 33), electrically controlled and suitably connected to one or more â € œPâ panels € included in said string â € œSâ €.

Said at least one central unit 3, following the interruption of the voltage of the power source 2, is able, through said control unit 32, to isolate at least one string â € œSâ €, interrupting the current in said string â € œSâ €, and dissect said string â € œSâ €, opening said plurality of switches (43 33), in such a way that said string â € œSâ €, is galvanically isolated and that at its ends there is at most a predetermined low voltage safety.

For the purposes of the present invention, the term at the ends there is at most a predetermined safety voltage means that at the ends of the string â € œSâ € there is a voltage between 0Vdc and a predetermined safety voltage as per the Safety Extra Low definition. Voltage. As shown in figure 1, the central unit 3 is connected to the power supply 2, which is preferably the mains voltage (240Vac 400Vac). Furthermore, said central unit 3 is connected to an inverter 10, generally included within the photovoltaic systems, to introduce the power produced by the â € œIâ € system in continuous mode, into the AC energy distribution network.

One or more peripheral units 4 are connected to said central unit 3, suitably connected to each other, for example connected in parallel or in series, according to the characteristics of the system â € œIâ €.

One or more series of â € œSâ € strings of â € œPâ € panels are connected to each peripheral unit 4, in which said â € œSâ € strings each include at least one â € œPâ € panel.

During normal use of the â € œIâ € system, each peripheral unit 4 connects the various â € œPâ € panels in series, included in each â € œSâ € string connected to it, to allow the production of electricity which is fed into the grid by the inverter 10.

The ends of one or more â € œSâ € strings connected to the respective peripheral units 4 reach said central unit 3.

Each peripheral unit 4 is connected to the central unit 3 via at least one data line 5, preferably a serial line, for example implementing the RS-485 standard.

Through said data line 5, the central unit 3 and in particular the control unit 32, can communicate with the single peripheral units 4, in order to disconnect one or more portions of the system â € œIâ €, in in case of danger or during the maintenance phases of the system itself.

In the embodiment illustrated in Figure 2, the control unit 32 is able to manage a plurality of switches 33, in use closed, included in the peripheral unit 4, able to open, so that at least one string â € œSâ €, or a section of it â € œSâ € ™, is galvanically isolated and that its ends have a pre-established low safety voltage, for example in case of interruption of the voltage of the power source 2 .

For the purposes of the present invention, the term switch means an electromechanical device adapted to interrupt the current in at least one portion of the electrical circuit by providing galvanic isolation between the contacts.

In the embodiment of Figure 2 said switches 33 are normally open electromechanical relays. Said relays comprise a coil which must be traversed by current, in order to be able to cause said switch 33 to close the contact, in order to realize the string â € œSâ €. The use of relays allows to have a galvanic isolation between the contacts through air gap, therefore, fully applicable in safety systems.

Removing the power supply voltage of the relays causes them to open, opening the electrical contact.

The opening of the switches 33, in a substantially simultaneous way, means that the breaking and sectioning capacity required of each individual switch 33 is reduced. This solution makes it possible to use relays with reduced contact dimensions, therefore, easily integrated into an electronic system, and with low consumption excitation coils.

The opening of the switches 33, included in a string â € œSâ €, allows the sectioning of the string â € œSâ € itself, for example at the level of each single panel â € œPâ €, intrinsically placing at least said portion of the system â € œIâ € sectioned, safely.

Preferably, two switches 33 are connected to each â € œPâ € panel, included in the â € œSâ € string, respectively a first switch connected to the cathode terminal and a second switch connected to the anode terminal of each â € œPâ € panel.

Preferably, the interruption of the power supply 2 occurs following the pressing of an emergency button 1. Said emergency button 1, according to the electrical safety standards, is a continuous switch, preferably by pressure, so that such that in the event of danger, for example a fire, power supply 2 is disconnected from the â € œIâ € system by simply pressing button 1.

This emergency button 1, in addition to being pressed in case of danger, can be pressed by an operator assigned to maintenance of the system, before starting maintenance on the system itself.

In the alternative embodiment, illustrated in Figure 3, the peripheral unit 4 comprises a plurality of switches (43, 33), and in particular at least one switch 33 suitable for interrupting a direct current, for example inside a string â € œSâ €, and one or more disconnectors 43, suitable for sectioning said string â € œSâ € into a plurality of â € œSâ € ™ sections galvanically isolated from the rest of the â € œIâ € system.

Said switch 33 is a relay suitable for opening a direct electric contact, interrupting the flow of current in the string â € œSâ €, extinguishing the electric arc generated during the opening of the contacts, ensuring electrical insulation.

Preferably, each switch 33 is placed in series with a string â € œSâ €, and has structural characteristics suitable for interrupting the current flowing inside the string â € œSâ € itself. In particular, said switch 33 is a relay, which comprises an electromechanical switch and a solid state switch, placed in parallel, so as to increase the performance of the switch 33.

The system according to the present invention, thanks to the plurality of peripheral units 4, allows to reduce the number of â € œPâ € panels included in each â € œSâ € string, allowing the use of switches 33 with reduced structural dimensions, since the breaking capacity It is lower.

A further method to reduce the breaking capacity required by the switch 33, for the opening of the contacts, and the consequent interruption of the current in the string â € œSâ €, it is possible to place more than one circuit breaker 33 in series, for example two.

Said one or more disconnectors 43, on the other hand, are suitable for sectioning said string into a plurality of string sections â € œSâ € ™ â €.

For the purposes of the present invention, the term disconnector means a switch capable of opening a line, guaranteeing galvanic isolation between the contacts when current flow is substantially absent on said line.

For the purposes of the present invention, the term substantially zero current means a current lower than 1/10 of the rated current flowing, in use, in the string â € œSâ €.

In particular, said disconnectors 43 have technical and functional characteristics such as to ensure insulation with an air gap, but without the need for the power to break the current.

In the event of a power failure 2, switch 33 is opened, blocking the flow of current in at least one â € œSâ € string. Following the interruption of the current in the â € œSâ € string, the plurality of disconnectors 43 is suitable for sectioning said â € œSâ € string, guaranteeing galvanic isolation.

The disconnectors 43 are preferably suitable for sectioning the string â € œSâ € at the level of each individual â € œPâ € panel included in the string itself. In particular, said disconnectors 43 can be, for example, two-exchange relays.

Preferably, two disconnectors 43 are connected to each â € œPâ € panel included in the â € œSâ € string, respectively a first disconnector connected to the cathode terminal and a second disconnector connected to the anode terminal of each â € œPâ € panel.

In the embodiment illustrated in detail in Figure 4, said central unit 30 comprises at least one energy storage device 34, capable of temporarily supplying said safety system in the event of a power failure 2.

This energy storage device 34, in a preferred embodiment, comprises a capacitor suitable for guaranteeing a predetermined voltage value, a capacitor charging device, suitable for stabilizing the energy coming from an energy source, for example the energy distribution network, in order to charge said capacitor, and at least one control device able to manage the charge of the capacitor itself in order to preserve its performances.

Said energy storage device 34, in one embodiment, is powered by one or more panels â € œPâ €.

Said control unit 32 also comprises at least one monitoring device 321, suitable for detecting the interruption of the power supply 2.

This monitoring device 321 monitors the power supply line 2 in order to detect, for example, a decrease in voltage below a predetermined voltage threshold.

Said predetermined voltage threshold corresponds, for example, to 1/10 of the rated voltage of the power supply 2. In the preferred embodiment, said monitoring device is, for example, a voltmeter suitable for measuring the voltage across the power supply. 2.

This solution allows to use disconnectors 43 instead of switches 33, requiring a reduced breaking capacity and reduced current consumption for the management of the system according to the present invention.

Said control unit 32 also comprises a data processor 322, suitable for processing the data coming from said monitoring device 321 and transmitting the appropriate signals to the peripheral units 4.

In particular, said data processor 322 is adapted to compare the voltage measured by the monitoring device 321 and compare it with the predetermined threshold voltage. If the voltage measured by the monitoring device 321 is below the aforementioned threshold voltage, the data processor 322 causes the system, according to the present invention, to secure the system â € œIâ €, or at least a portion of it.

Said control unit 32 is also suitable for executing a computer program, suitably stored on a non-volatile memory support, suitable for carrying out a series of operating phases, preferably consecutive, suitable for securing solar systems (I ) for the generation of electricity.

This program carries out the following operational phases: â € ¢ power supply monitoring 2;

â € ¢ power supply reduction detection 2 below a predetermined threshold;

â € ¢ opening of the electrical circuit of one or more â € œSâ € strings;

â € ¢ string sectioning â € œSâ €, into string sections â € œSâ € ™ â €;

â € ¢ Galvanic isolation of the string section â € œSâ € ™ â € with a pre-established safety low voltage at its ends.

The power supply monitoring phase 2 provides that the monitoring device 321 monitors the power supply 2 in order to detect, for example, a reduction in the voltage of the power supply 2 below a predetermined threshold.

Said monitoring device 321 continues to monitor line 2 by sending, for example at regular intervals, the voltage measurement to the control unit 32 and in particular to the data processor 322. In case of reduction, for example, of the power supply voltage 2, the value measured by the monitoring device 321 sent to the data processor 322 will be lower than the preset threshold. In the phase of detecting reduction of the power supply 2 below a predetermined threshold, the data processor 322 detects that the voltage measured by the monitoring device is below the predetermined threshold. Subsequently, we move on to the phase of opening the electric circuit of one or more â € œSâ € strings. In said phase the control unit 32, preferably the data processor 322, sends the opening command to the switches 33, to which, in the preferred embodiment, the coil is disconnected by opening the relay contacts.

The phase of sectioning the string â € œSâ €, into sections of the string â € œSâ € ™ â € in the embodiment illustrated in Figure 2 occurs at the same time as the opening phase of the electric circuit mentioned above. The control unit 32, preferably the data processor 322, simultaneously sends the opening signal to all the switches 33.

In the embodiment illustrated in figures 3 and 4 the disconnection takes place after the electric circuit opening step after a predetermined period of time. In fact, the control unit 32, preferably the data processor 322, initially sends the opening signal to the circuit-breaker 33 and subsequently, after a predetermined period of time, the opening signal to the disconnectors 43. predetermined time is substantially the average time necessary for the circuit-breaker 33 to reduce the current circulating inside the string â € œSâ € below a predetermined threshold close to zero. This period, therefore, corresponds on average to the reaction time of the circuit-breaker 33. Therefore, it is possible to set the time between the opening signal of the circuit-breaker 33 and the disconnectors 43, according to the technical characteristics of both the switch 33, and in particular the switching time, and of the disconnectors 43, for example the size of the contacts.

Preferably, said phase of sectioning the string â € œSâ € is carried out after the complete cancellation of the current in the string â € œSâ € following the phase of opening the electric circuit.

Subsequently, we move on to the galvanic isolation phase of the string section â € œSâ € ™ â € with a pre-established low safety voltage at its ends. In this phase, following the sectioning phase, galvanic isolation is guaranteed at the ends of said portions of the string â € œSâ € ™ â €. At the ends of these portions of string â € œSâ € ™ â € there is a low voltage in compliance with the electrical safety regulations. Preferably, called portions of string â € œSâ € ™ â € includes only one panel â € œPâ € since the sectioning of the string â € œSâ € occurs at the level of each single panel â € œPâ € which at its ends, in use it has a voltage fully compliant with electrical safety regulations.

In the preferred embodiment, the central unit is placed near the safety button 1, for example near the electrical panels of the system â € œIâ €, while each peripheral unit 4 positioned near one or more â € œSâ € strings connected to it.

The various peripheral units 4 are preferably connected in series with each other. The peripheral unit 4 includes a protective casing designed to protect the electronic devices, included therein, from bad weather, since it is normally placed close to the series, in non-insulated places.

Both the central unit 3 and each peripheral unit 4 are fully compliant with the regulations in the field of electromagnetic compatibility.

In the embodiment, illustrated in Figures 3 and 4, each peripheral unit 4 is connected to a single string â € œSâ €, which is composed of a plurality of â € œPâ € panels, and includes a switch 33 one plurality of disconnectors 43, preferably two disconnectors 43 for each â € œPâ € panel included in the string â € œSâ €.

The system according to the present invention can be connected to a computer, or to a personal computer for remote monitoring of the system through a connection implementing, for example, the Ethernet protocol. In particular, the central unit 3 can be connected to a computer network, and the second system, the present invention, can be activated remotely.

The central unit 3 is connected via a second data line 51 with the inverter 10 in such a way as to be able to obtain additional information on the â € œIâ € system and the energy distribution network, in such a way to be able to intervene promptly, for the safety of the â € œIâ € system, or at least a portion of it, in the event of danger or malfunctions of the system itself.

Claims (9)

CLAIMS: 1. System for securing one or more solar plants (I) for the generation of electricity, each plant comprising a plurality of solar panels (P), in use, electrically connected in series to form one or more strings ( S); characterized by the fact of understanding: â € ¢ at least one central unit (3), electrically connected to one or more of these strings (S) of panels (P) and to a power source (2) suitable for powering said safety system, comprising at least one control unit (32); â € ¢ at least one peripheral unit (4), electrically connected to at least one string (S), and to said central unit (3), comprising a plurality of switches (43, 33), electrically controlled and suitably connected to one or more panels (P) included in said string (S); said at least one central unit (3), following the interruption of the voltage of the power supply source (2), is able, through said control unit (32), to isolate at least one of the strings connected to it, interrupting the current in said string (S) and disconnecting said string (S), opening said plurality of switches (43), in such a way that said string is galvanically isolated and that at its ends there is at most a predetermined low safety voltage . System according to claim 1, wherein said plurality of switches (43, 33) comprises: at least one switch (33) adapted to interrupt a direct current, one or more disconnectors (43), suitable for sectioning said string (S) into a plurality of galvanically insulated sections (Sâ € ™). 3. System according to claim 1, wherein said central unit (30) comprises an energy storage device (34), adapted to temporarily power said safety system in the event of a power failure (2). 4. System according to claim 1, wherein said control unit 32 comprises at least a monitoring device (321), suitable for detecting the interruption of the power supply (2) and a data processor (322), suitable for processing the data coming from said monitoring device (321) and transmitting the appropriate signals to the peripheral unit (4). 5. System according to claim 1, wherein the system comprises a plurality of switches (33), each one adapted to isolate a single string (S). 6. System according to claim 1 or 5, in which each peripheral unit (4) is connected to a single string (S) and comprises a plurality of disconnectors (43) suitable for sectioning the string (S) by isolating each single panel ( P) included in the string (S). 7. System according to claim 1, in which the interruption of the power supply (2) occurs following the pressing of an emergency button (1). 8. System according to claim 3, in which the energy storage device (34) is powered by one or more panels (P) System according to claim 7, wherein said emergency button (1) is a continuous switch. Barzanò & Zanardo Milano S.p.A.