ITRM20110625A1 - METHOD AND PLANT FOR RADIO IDENTIFICATION FREQUENCY GEOREFERENTIATED FOR TRACKING AND BURGLAR ALARM FOR PHOTOVOLTAIC PANELS - Google Patents

Description

â € œMETHOD AND GEOREFERENTIATED RADIO FREQUENCY IDENTIFICATION SYSTEM FOR TRACKING AND ANTI-THEFT FOR PHOTOVOLTAIC PANELSâ €

DESCRIPTION

The present invention relates to a georeferenced radio frequency identification method and system for tracing and anti-theft deterrence of photovoltaic panels.

The present invention, in particular, refers to anti-theft and / or anti-theft deterrent systems for photovoltaic panels, usable both for civil installations (i.e. small sizes up to 20 kW) and for industrial installations ( i.e. above 20 kW).

Currently, various anti-theft identification systems for photovoltaic panels are known, already published on international online databases such as Espacenet and USPTO (United States Patent and Trademark Office).

Said known systems are basically based on optical systems, anti-intrusion systems, active GPS systems, â € œbeacomingâ € systems, systems with measurement of the voltage produced by a string of modules connected in series, beaconing control systems with â € œpairing one on oneâ € through RFID, systems with â € pairingâ € between the conversion system and production systems with the use of electrically writable memories, and of all said systems below we proceed to highlight the relative disadvantages, also through their synthetic previews description, where deemed necessary.

Optical type systems, such as the US patent US2010141424 (A1), use fiber optic cables connected to the modules by means of bolted joints and allow the possibility of evincing an attempted theft from the simple interruption of a cable.

Optical type implants basically have the following disadvantages:

- they require high labor costs both for installation and for subsequent ordinary maintenance;

- the cables are easily identifiable and in any case it is always possible, where the system area is not properly monitored, to release the panel from the anti-theft system making the system ineffective.

The anti-intrusion systems, on the other hand, are based on intrusion detectors (microphone sensors, infrared bars, perimeter systems). They are effective in detecting intrusion, but have the following disadvantages:

- the costs of the detection means are currently high, especially for small plants;

- they are extremely sensitive to false alarms due to the presence of fauna, even small ones, usually present in the installation areas.

The active GPS systems, in turn, constantly monitor the position of the photovoltaic panels, detecting any movement from the installation area (ENEA PV Guardian patent). The relative disadvantages are due to the fact that:

- they have non negligible costs relating to components;

- create considerable problems during the manufacturing process of photovoltaic panels.

The systems with â € œbeaconing activeâ €, on the other hand, are anti-theft systems based on the interruption of the operation of the panel when the system present in the panel no longer recognizes the presence of the â € œbeaconâ €. The disadvantages presented by these latter are due to the fact that:

- although they can be integrated into the photovoltaic panel, they require more time for their manufacturing process;

- they can cause erroneous malfunctions, in case of false â € œbeaconâ € signals.

Systems with the measurement of the voltage produced by a string of modules connected in series (for example those produced by SMA inc.) Have the disadvantage of not working during off-feeding periods (evening, night).

In addition to this methodology, a US patent US2011032099 (A1) has been presented, according to which a test current is injected by modifying the conversion system (inverter) during off-feeding periods. However, this methodology requires significant interventions in the production processes of the photovoltaic modules, as well as in the architecture of the photovoltaic production plant itself.

The systems with â € œbeaconing with pairing one on oneâ € control using RFID, as per international patent application WO2007144036 (A1) of 21.12.2007, are equipped with an RFID transponder and a reader, respectively integrated in the photovoltaic module and in the support. ; the reader continuously detects the presence of the transponder and is also able to detect even small movements, immediately determining the theft. The disadvantages of this type of system are basically due to the fact that:

- the installation of the transponder and the reader have the drawback of being invasive as regards the production of the supports;

- therefore, their installation costs are high;

- The overall cost of the system is also necessarily high.

The systems with â € œpairingâ € between the conversion system and production systems with the use of electrically writable memories, such as the US patent US2010301991 (A1), store the â € œpairing codeâ €, which code may depend on the GPS geographic coordinates. The pairing is inserted during the installation and / or production phase and, in the case of installation through other devices connected to the production network. In this case, the anti-theft system provides for the continuous reading of the code by a subsystem installed on the inverter. The disadvantages of this type of system are basically due to the fact that:

- A significant re-engineering of the conversion systems is necessary, with the addition of communication control subsystems; - It is possible to use wireless systems with centralized architecture or â € œmeshâ €, but not RFID; - does not refer to specific memory architectures;

- the possibility of â € œtrackingâ € of the original installation position of the module is not clear.

Also known are the US patent US2010236598 (A1) entitled â € œEmbedded RFID solution for solar panelsâ € and the European patent EP2150986 entitled â € œPhotovoltaic device comprising an RFID safety device and method for the production thereofâ € of SOLARTEC, both related to a methodology for incorporating an RFID TAG in a photovoltaic module. The first refers explicitly to the possibility of using it as an anti-theft mechanism and to the possibility of entering information on its location, without any mention of its control methods. In the second there is no mention of GPS coordinates.

Another European patent is also known, EP2150986 (A2), relating to the production process of an integrated module with an RFID TAG in which information not well identified in the relative descriptive report is stored.

Another US patent US2005134462 (A1) is also known, relating to an RFID tag equipped with a photovoltaic cell connected to a battery for â € œrange extensionâ €.

From the previous analysis carried out of the technique known to date in the field of anti-theft and / or anti-theft deterrence systems for photovoltaic panels, it is possible to deduce how the sudden and perhaps unexpected spread of generation plants based on energy sources renewables, in our particular case the photovoltaic ones, was a consequence of the dependence until yesterday necessary on fossil sources, whose continuous cost increase, due to speculations, taxes and availability estimates, together with the recent government incentive devices in favor of renewable sources , has entailed greater investments in the latter. These major investments have occurred precisely in the photovoltaic sector and the considerable cost (albeit in a recent decrease) of photovoltaic panels has followed an â € œescalationâ € of thefts of the same panels, also due to the fact that most of the industrial installations It is located in extra-urban areas that are difficult to control in case of theft.

The current anti-theft protection systems, as already highlighted in the previous analysis of the prior art, are fundamentally based on: - anti-intrusion systems easily exposed to problems of false alarms, often due to the presence of fauna in the surroundings of the same plants ;

- traditional anti-burglary systems that can be easily circumvented and, therefore, ineffective;

- optical / electrical connection systems (â € œsewingâ €) with fiber cables, which for reasons of visibility can be easily identified and finally evaded;

- recent systems based on inverter / module coupling or similar, which have a significant impact on the design and development techniques of the systems and / or the panel itself, and are also not competitive in terms of cost, especially for small-sized systems.

The main purpose of the present invention is, therefore, to realize a method, and the relative plant, of georeferenced anti-theft radio frequency identification for photovoltaic panels and integrated photovoltaic module, which fully resolves said disadvantages of the known technique, in in particular, it solves the technical problem of anti-theft protection with real-time detection of any tampering and theft attempts with concealable and irremovable devices.

Further purposes of the present invention, no less important than the previous one, are to provide a method which:

- makes significant progress in the engineering phase of the photovoltaic system, reducing the additional costs both of the engineering phase itself and of the subsequent development phases of the modules and inverters; - allows its simple integration into current manufacturing processes;

- brings significant cost reductions compared to production methods based on RFiD technology both in the installation and maintenance phases;

- allows the creation and / or use of high efficiency but low cost devices; - allows high simplicity of the theft verification process;

- allows the anti-theft protection of photovoltaic fields, both small and large, with extremely minimized costs;

- allows the identification of the first installation location and, therefore, the certain traceability of any stolen panels, allowing the police to reconstruct the illegal traffic channels;

- finally, allows the complete tracing of the panel from its manufacture to its disposal

Furthermore, the present invention has been conceived and studied in order to be used both for civil applications and for industrial applications.

These purposes are achieved by creating a solution that exploits the anti-theft georeferenced radio frequency identification technology 1 for photovoltaic panels 2 and integrated photovoltaic modules 3, characterized by the fact that each individual photovoltaic panel is associated with a wireless device to give rise to an architecture with nodes connected to a fixed, mobile or distributed reading system.

In a first embodiment, said architecture is an active node, said system 1 being made up of:

a set of panels each of which equipped with a node with univocal identification with a microcontroller equipped with a transceiving element 4 with power supply from a buffer battery. The battery is connected to the photovoltaic module. The connection topology is mesh; And

control software components capable of monitoring the signal from neighboring nodes.

In a second embodiment, said passive node architecture, being said system consisting of:

a set of panels each of which is equipped with a radio frequency identification label (RFID) or passive TAGs 9 identifying the single photovoltaic panel 2 and / or the single integrated photovoltaic module 3, with said photovoltaic panels 2 and photovoltaic modules 3 equipped with geographic information, obtainable directly or indirectly by interrogation or simple reception by means of transceivers or GPS 5.

These objects and the consequent advantages, as well as the characteristics of the invention according to the present invention, will be more clearly evident from the following detailed description of some preferred solutions, given by way of example, but not limited to, with reference to the attached drawings, in which:

- Fig. 1 is a three-dimensional schematic view of an anti-theft georeferenced radio frequency identification system 1 for photovoltaic panels 2 and integrated photovoltaic modules 3 according to the present invention, which shows a set of photovoltaic panels 2 equipped with active radio frequency or RFID TAG interconnected devices 4, suitable both to identify the single panel 2, and to geolocalize it through a geographic information obtainable through its interrogation by GPS receivers 5; this graphic representation is valid both in the case of generalized architecture of system 1, and in the particular case of architecture of the first type â € œGeo-WINSâ € with interconnected active nodes and possibly equipped with transceiver means or GPS 5;

- Fig. 2 is a three-dimensional schematic view of a single integrated photovoltaic module 3 constituting the photovoltaic panel 2 (or also, alternatively, a photovoltaic panel 2), of which it has been highlighted with a circle â € œPâ € ( that represented three-dimensionally appears elliptical) the detail enclosing a proximity detector or passive TAG 9 applied in an integrated way to the same module 3 (or panel 2);

- Fig. 3 is an enlarged schematic plan view of said passive TAG 9 referred to in detail â € œPâ € of the previous figure, together with said GPS 5 device (represented three-dimensionally) operated directly or remotely by a man 10 ( shown schematically), all to schematize in a graphic way the interrogation mode of the photovoltaic modules 3 (or, equivalently, of the panels 2) in case of control following the theft of the photovoltaic panels by the supervisory inspection bodies or forces of law and order; - Fig. 4 shows a logical block diagram 12 of the process of certain tracing and univocal identification of the panel 2 or of the integrated photovoltaic module 3 that composes it and of the relative original installation location, in order to allow the identification, in a subsequent inspection check of the same panels 2, the unmotivated movement of the panels, their theft or their disposal.

BRIEF DESCRIPTION OF THE INVENTION

As can be seen from the attached figures, in particular figures 1, 2 and 3 attached hereafter, the present anti-theft georeferenced radio frequency identification system 1 for photovoltaic panels 2 and integrated photovoltaic modules 3 is a wireless system for deterrence and protection from theft of photovoltaic panels 2. The system is based on radio frequency devices 4-9 which are able to uniquely identify the single panel 2, and are equipped with geographical information, obtainable by interrogating them by means of transceivers o GPS 5.

System 1 can be specialized in two distinct architectures, integral parts of the invention in question.

In the first case, module 3 or photovoltaic panel 2 is equipped with a wireless device of the RFID or active TAG type or transponder 4 capable of connecting with other TAGs or active nodes 4, creating a connected grid topology, by means of the installation of a plurality of interconnection means 11, indicated in Fig. 1 through connection lines between said TAGs or active nodes 4. The detection of thefts takes place by comparing the geographical coordinates finalized at the time of installation and the current ones or, more simply, by monitoring the perceived distance between the different active nodes 4. In this case, if an active node 4 perceives the increase in distance from the proximity nodes 4, through the perception of the significant decrease in the signal power received at cause of the removal of the other TAG 4 in case of removal or theft of panel 2, the attempted theft is determined with certainty.

In the second case we refer to a unique labeling system using proximity RFID devices or passive TAGs 9, which allows the geolocation of the photovoltaic panels for the purpose of deterring and protecting them from theft.

The present invention also describes, as schematically shown in Figure 4, a procedure 12 for using the invention for the purpose of identifying stolen photovoltaic panels 2.

Said procedure 12 allows the tracing of the place of first installation of the panels 2. The geolocation of the TAG, active 4 or passive 9, takes place during the installation phase by means of a transceiver 5 or portable reader / writer equipped with a GPS receiver, that is to say, even a smartphone with an RFiD reader such as NFC.

The control takes place during ordinary maintenance or inspection by controllers 10 or control bodies in charge. In this phase, the operator assigned to control 10, equipped with said GPS 5 transceiver means, can check the finalized geolocation of the TAG 4-9, comparing them with the current coordinates, causing a possible theft. With this method it is also possible to identify any illegal traffic channels of stolen photovoltaic panels 2, thus also facilitating the work of the police.

In both cases the active nodes 4 or passive 9 can be hidden and integrated with the module 3 at different levels. If the nodes 4-9 are to be integrated during the manufacturing phase, they can be either integrally integrated with the panel 2 (integral lamination or integrated geometry for the RFID nodes 9, partial lamination for the autonomous nodes 4). In subsequent stages they can be simply connected to fixed parts of the panels 2 (preferably in hidden parts or to be concealed on the back of the panel), in an immovable way by means of adhesives and sealants, with negligible impacts on the current manufacturing processes and subsequent disposal processes. .

DETAILED DESCRIPTION OF THE INVENTION.

The present invention is characterized with respect to the known art precisely by the fact that it uses wireless devices which are simple to install, configure and low cost.

The architecture is characterized by the integration with different methodologies of the single photovoltaic panel 2 with wireless devices of different architecture, connected to a fixed, mobile or distributed reading system, carrying out continuous or deferred readings, in order to control the location information of the nodes themselves, consisting of active 4 or passive 9 TAGs.

In a first verticalization of the proposed architecture, called active node 4, the system basically consists of a set of photovoltaic panels 2, each of which equipped with a node 4 with univocal identification with microcontroller equipped with a transceiver element with power supply backup battery. The battery is connected to the photovoltaic module 3. The connection topology is â € œmeshâ €. The active control components 4 are able to monitor the signal coming from neighboring nodes, even if of the passive type 9.

In this architecture each single node 4 is able to detect its own movement or the movement of a neighboring node 4-9, easily recognizing any tampering event.

A special module operating from â € œdata sinkâ € and possibly located at the inverter can, interacting with the electricity network or by signaling on the data network, draw attention to any attempted theft.

The single node 4 can also make the panel 2 unusable by modifying the connection architecture between the cells or photovoltaic modules 3 of its physical components.

In a second verticalization of the proposed architecture, called passive node 9, system 1, as shown in Fig. 1, is made up of a set of panels, each of which is equipped with a radio frequency identification label (RFID ) also in NFC declination, also called passive TAG 9.

â € œNear Field Communicationâ € (NFC) is a technology that provides short range bidirectional wireless (RF) connectivity (ie up to a maximum of 10 cm). The technical specifications of NFC technology are based on ISO standards 15693, 18092 and 21481, ECMA 340, 352 and 356 and ETSI TS 102, 190.

NFC is also compatible with the widespread architecture of â € œsmart contactless cardsâ €, based on the ISO 14443 A / B, â € œPhilips MIFAREâ € and â € œSony FeliCaâ € airborne protocols.

In particular, for the proposed solution, transponders or TAG 4-9 with ISO 14443 A air protocol can be used, with user memory protected by password.

By operating according to the process represented in Fig. 2, with these architectures it is possible to identify stolen and reinstalled panels. Furthermore, through the use of geographic information, it is possible to identify any channels of receipt of the stolen product for possible use by the forces of law and order.

Both architectures are susceptible of ferent node 4-9 / panel 2-3 module integration technologies. By exploiting the architecture of an RFID tag and its possibility of being disguised to avoid â € œtamperingâ € events, the passive node can be glued on different surfaces of the panel: internal / external.

An alternative with a different impact on the manufacturing processes consists in the lamination of the label also in the â € œsandwichâ € configuration inside the photovoltaic module 3, making its separation from the module itself impossible.

Part of the passive node 9 can also be laminated with similar procedures. It is also possible to fix part of the node, with classic methods, to the back (also inside) of the panel itself.

In summary, the system object of the invention has the following innovative aspects:

for active node 4:

- photovoltaic panel 3 of the intelligent type, ie equipped with an active wireless node 4, possibly with GPS technology;

- detection of thefts by comparing GPS coordinates or received signal strength level;

- possible power supply of the battery of the wireless node 4 with energy supplied by the same panel 2;

for passive node 9:

- smart panel equipped with unique RFID tag 4 geo-referenced for purposes of tracking and deterrence from theft;

- immediate detection of thefts by comparing GPS coordinates;

These elements allow an innovative approach to protection / deterrence from theft in photovoltaic systems of highly variable size thanks to the minimized cost of these solutions.

Diagram 12 represented in Figure 4 shows a block logic diagram of the active 4 or passive 9 TAG.

The start of the unique identification process â € œAâ € of the panel 2 or of the integrated photovoltaic module 3 that composes it first sees the â € œBâ € phase of integration of TAG 6-9, followed by the registration phase â € œCâ € of the data concerning the unique identification code of the same TAG 6-9 and, therefore, from the finalization phase â € œDâ € of the registration of the TAG 6-9 with â € œlâ € ™ imprimiturâ € of the original installation location of the panel 2 or of module 3. A said first three consecutive â € œAâ € -â € œBâ € -Câ € production phases of module 3 or photovoltaic panel 2 (in any case involving only minimal increasing variations in their manufacturing time cycle), the following phase â € œDâ € (detached in time from the previous ones, as can be seen from the relative arrow connecting the phases, now no longer continuous, but dashed and crossed out) marks the beginning of the installation time of system 1. The subsequent phases â € œEâ € (time marker for iodic throughout the TAG operating life cycle), â € œFâ € (position control function with finalized GPS coordinates) and â € œGâ € (notice of necessary intervention for general maintenance of the system 1) constitute a feed-back cycle of the logical block diagram 12 of the active 4 or passive TAG 9. In fact, the phases â € œEâ €, â € œFâ € and â € œGâ € act as the control â € œloopâ € of the correct â € œstatus quoâ € of the system 1 . In an alternative case, the system 1, detecting the unmotivated movement of the panel 2 in a subsequent check, launches an alarm indicating its theft or the break-in of at least one panel 8 of the same system and, in this case, activates the â € œreport of theftâ € (phase â € œHâ €) to the police or to the authorized controller 10.

As can be seen from the above description and from the figures attached hereto, the main advantages of the system object of the present invention, with reference to the systems identified, are innumerable and of undoubted importance in the sector of the installation of photovoltaic panels.

The main advantages of this georeferenced anti-theft radio frequency identification system for photovoltaic panels and integrated photovoltaic module compared to the technological solutions available today are:

- low cost of the devices used;

- ease of integration into the current manufacturing processes of photovoltaic panels;

- possibility of integration of this system also post-manufacturing with total absence of impacts, in particular on the current manufacturing processes of particular configurations;

- absence of complex installation operations; - simplicity of the theft verification and identification process;

- possibility of tracing channels for receiving stolen product.

These advantages allow the protection of photovoltaic systems even of considerable size at extremely low costs, since all the costs relating to the technologies and devices necessary for the realization of the system have been minimized, which can also be validly installed on both small and very small systems. dimensions, allowing the identification of the first installation location of any stolen photovoltaic panels, in order to trace back to the plant of origin, assisting the police in the reconstruction of the illegal traffic channels of the same.

Further advantages are due precisely to the simplicity of the constructive characteristics of the system, which result in the further advantage of minimizing manufacturing costs and, therefore, costs to end users.

It is also evident that numerous retouching, adaptations, additions, variations and replacements of elements with other functionally equivalent may be made to the example of realization previously described for illustrative and non-limiting purposes, without however leaving the scope of protection of the following claims.

LEGEND

1. anti-theft georeferenced radio frequency identification system

2. photovoltaic panels

3. integrated photovoltaic module constituting the panel 2

4. active radio frequency devices (TAG RFID) 5. portable transceiver or reader / writer equipped with GPS receiver

6. Detection radio waves transmitted by active RFID TAGs

. radio waves received by transceivers or GPS 5

. radio waves transmitted by transceiver means or GPS 5

. passive TAG devices integrated in the single module 3

0. controller or control body in charge

1. means of connection or interconnections between panels 2

2. logic block diagram

A. Start of the univocal identification process of the panel 2 or of the integrated photovoltaic module 3 that composes it and of its original installation location (a subsequent check may highlight the unmotivated movement of the panel indicating its theft) B. Interrogation of the integrated RFID TAG in the photovoltaic module 3 of panel 2

C. Finalization of identification

D. Finalization of the TAG with the installation location

E. Operating life time

F. Function of interrogation of the regular step of maintenance of the operating life time

G. Notice of need for general maintenance H. Report of theft of the photovoltaic panel 2

Claims (11)

CLAIMS 1) Anti-theft georeferenced radio frequency tracking and identification method (1) for photovoltaic panels (2) and integrated photovoltaic modules (3), characterized by the fact that it provides for the irremovable equipping of each single panel (2) or integrated module (3) of a photovoltaic system, of RFID or active TAG radio frequency devices (4) and / or passive RFID or TAG proximity devices (9), designed to identify the single photovoltaic panel (2) and / or the single module integrated photovoltaic (3), and to allow its geolocation, obtainable directly or indirectly through interrogation or simple reception by means of transceivers or GPS (5). 2) Method according to the previous claim, characterized by the fact that the identification of thefts takes place through the comparison between the geographical coordinates intended at the time of installation and those current at the time of the interrogation or, more simply, through monitoring of the perceived distance between the different active nodes made up of said active TAGs (4). 3) Method according to the preceding claims, characterized by the fact that the monitoring of the perceived distance between the different active nodes or TAGs (4) is perceived as increasing when there is a significant decrease in the signal power received by the same active TAG (4), thus determining the identification of an attempted theft. 4) Method according to the previous claims, characterized by the fact that the identification of the stolen photovoltaic panels (2) takes place beforehand by tracing their place of first installation by means of the geolocation of the active (4) and / or passive (9) TAGs ) during installation by means of a transceiver or portable reader / writer equipped with a GPS receiver (5), such as, for example, a latest generation mobile phone. 5) Method according to the preceding claims, characterized by the fact that the control of said panels (2) and modules (3) takes place during ordinary maintenance or inspection by controllers or control bodies in charge (10) equipped with said transceiver means Portable GPS (5). 6) System for georeferenced anti-theft radio frequency identification (1) of photovoltaic panels (2) and integrated photovoltaic modules (3) characterized by the fact that each single panel (2) or integrated module (3) of a system photovoltaic is equipped with radio frequency devices RFID or active TAG (4) and / or RFID proximity devices or passive TAG (9), installed in an immovable way and able to identify the single photovoltaic panel (2) and / or the single integrated photovoltaic module (3), and to allow its geolocation, obtainable directly or indirectly by interrogation or simple reception by means of transceivers or GPS (5). 7) System as in the previous claim characterized by the fact that said active (4) and passive (9) TAGs can be concealed and integrated within the photovoltaic module (3) or integrally with the photovoltaic panel (2) through integral lamination or integrated geometry for active RFID or TAG nodes (4) or partial lamination for autonomous nodes or passive TAGs (9). 8) System according to claims 6 and 7, characterized by the fact that said active (4) or passive (9) TAGs are connected in an immovable and occult way to fixed parts of the same photovoltaic panels (2), preferably on the back of the panel, simply using adhesives and sealants, minimizing the impact of their installation on current manufacturing processes. 9) Plant as per claims 6 onwards characterized by the fact that in a first preferred architecture, each photovoltaic module (3) is equipped with an RFID or active TAG wireless device (4) capable of connecting to the other active TAGs (4) present on the other panels (3) through a plurality of connection means (11), thus creating a connected grid topology, absolutely valid against the theft of the panels. 10) System according to claims 6 onwards, characterized by the fact that, in a second preferred architecture, said photovoltaic module (3) and / or integrated photovoltaic panel (2), is equipped with a unique geolocalized labeling system by means of TAG Passive RFIDs (9), said architecture being valid as a means of deterring and protecting against theft. 11) System according to claims 6 onwards, characterized by the fact that it is equipped with a controller (10) or control bodies in charge equipped with a GPS transceiver means (5) which is able to compare the finalized geolocation of said Active (4) or passive (9) TAGs with current coordinates, thus determining a possible theft and, possibly, identifying any channels of illegal trafficking of stolen panels, facilitating the work of the police.