IT201600116906A1 - Device to detect and prevent theft of electricity - Google Patents

Description

Device to detect and prevent

the theft of electricity

DESCRIPTION

The present invention relates to a device produced to detect and prevent the theft of electricity.

The field of the invention is that of controlling the consumption of electricity in industrial and similar domestic networks.

In the use of electricity, the importance of being able to carry out adequate checks for a correct accounting of consumption billed by electricity operators is increasingly emerging. For this purpose, there are various solutions, also offered by the suppliers themselves, but none of these systems protect the user from the risk of suffering energy theft.

In fact, the position of the electricity meters does not coincide with the users' premises, indeed often located elsewhere, in distant points, leaves the bad guys the possibility of making illegal withdrawals, by accessing the electrical risers placed between the point of supply of electricity , coinciding with the meter device, and the regular consumer.

The current impossibility of detecting and preventing these thefts with the systems in use, can expose legitimate users to burdensome economic disputes with suppliers because they could be unfairly forced to pay for consumption that is the consequence of a theft suffered.

Therefore, the main purpose of the present invention is to provide a device suitable both for detecting abusive electrical energy withdrawals and for preventing them also automatically.

These and other purposes are achieved with the device of claim 1. Preferred ways of carrying out the invention result from the remaining claims.

The device of the invention is therefore aimed at all consumers to whom the relative electric meter has been installed outside the private spaces used by the legitimate user.

It should be noted, and underlined, that the electrical risers that transfer energy from the meter to the end user, despite being placed in exposed places outside the private perimeter of the user, are considered by the energy suppliers as an integrated part of the system. electricity of the consumer, and conceptually a current withdrawal from any point of said risers is a matter of strict relevance to the legitimate user, even in the event of overt theft.

Since the cost of electricity has become very high not only for the various excise duties, but even more so due to the load of incentives for renewable energy, spread over time on the consumption of all users, the risk of being charged high amounts suggests the need for protection and this project represents the complete solution to the problem. Thanks to the characteristics indicated in the cited claims, the device of the present invention offers the advantage of allowing the user to be informed about theft attempts and to intervene on them, preventing them in the ways that are preferred for him.

Furthermore, the invention can be exploited by the same electricity suppliers who could, for example, integrate the unit located near the meter directly into the body of the meter itself and provide a paid service by renting the unit to be installed to the end user. the latter who, paying a modest sum, would make sure that no one can rob him. The energy suppliers themselves would benefit not only from the proceeds of the system's rents, but also from the fact that users, in cases of theft, finding themselves having to unfairly pay expensive bills for consumption made by others, often, also out of frustration, refuses to pay, opening a dispute, which is often resolved with the passage to another supplier, or with a change of the holder of the supply or even with the abandonment of the premises, leaving the disputed invoices unsolved, thus causing evident damage economical for suppliers.

These and other purposes, advantages and characteristics result from the following description of a preferred way of realizing the device of the invention illustrated, by way of non-limiting example, in the figures of the attached drawings.

In them:

- figure 1 represents the diagram of a usual wiring for the supply of electric energy to a user;

- Figure 2 illustrates the wiring diagram of the invention wiring;

- Figure 3 illustrates the general diagram of the operation of the device of the invention;

- Figure 4 illustrates the block diagram of a preferred way of realizing the unit 8 of the diagram of Figure 3, located in the vicinity of, or associated with, the meter;

- Figure 5 illustrates the block diagram of a preferred way of creating unit 9 of the diagram in Figure 3, located at the end user.

The wiring diagram in figure 1 includes a meter 1 of the electricity consumption made by the user 2 through the cables, or electrical risers, 3 and 4.

Generally, electricity suppliers ask and obtain to install their consumption meters 1 outside the user premises, and therefore there is a special line of cables 3 and 4 that transfers the current from the meters to the homes of legitimate customers. This line is the critical part of the system, as it can have a long and hidden path, located in special compartments that are not immediately observable, and often it is even difficult to identify your line because it is often joined in bundles of different cables. Among other things, the abusive withdrawal of electricity could also be discontinuous (for example seasonal), so after the arrival of an unjustifiably excessive bill, the electrician paid and sent to check may not find the theft.

Illicit withdrawal of electricity is carried out precisely by connecting the cables 3 and 4 of branches 5 and 6 of electricity to an illegal user 7. In this way, the consumption measured by the meter 1 is the sum of the electricity consumption of the user 2 and users 7.

The described scheme of the prior art, that is, without the use of a system as the object of the present invention, does not however allow the regular consumer, who uses the user 2, to receive any notice of the withdrawal of electricity carried out by the user. abusive 7.

Considering the significant economic damage that a power draw could (a posteriori) cause to the unaware user and the objective difficulty, both in trying to protect his own power line, and in periodically checking that there are no abusive connections, the inventor has devised the device of the present invention which, in real time and without the possibility of error, is able to immediately detect even the smallest abusive current draw, and to intervene according to the settings that the customer can define and prepare through the '' setting the parameters of the device itself.

Therefore, to overcome the aforementioned drawbacks and to allow the regular user to be aware of any illicit withdrawals of electricity, the device of the invention according to the diagram of figure 2 comprises either a unit 8 located near the electricity meter 1 or also directly integrated in this, both in a unit 9 located at the end user 2.

As better illustrated in Figure 3, the aforementioned unit 8 comprises a meter 10 of the total current delivered by the counter 1 (reference A in Figures 3 and 4) and also includes a control logic 11, which receives the value in real time from the meter 10 of current actually delivered by the counter 1. The same control logic 11 also receives at the same time from the unit 9, which will be better described below, a periodic command whose presence causes the same logic 11 to keep the relay module 12 in the closed state of the circuit. In unit 8 there is also module 13 which deals with the bidirectional transmission (TX / RX) of the information provided by the control logic 11 to the aforementioned unit 9 and vice versa sent using the same electrical uprights 3 and 4.

It should be noted here that the described unit 8, although defined in this way, can be made as an integral part of the meter 1 installed by the distributor with important advantages in terms of costs, space, reliability and safety, since most of the components described are already present in counter 1 and for some recently produced meters, potentially, only an update of the equipment management software 1 may be sufficient.

The unit 9 located at the end user 2 in turn comprises a meter 14 (reference A in Figures 3 and 5) of the current in transit actually consumed by the user 2. The unit 9 also includes a control logic 15, whose function is to receive from the meter 14 the current values detected in real time which define the actual consumption of the user 2, and then compare it with the information relating to the current readings in real time coming and communicated by the unit 8 through its module 13, the electric uprights 3 and 4 and the corresponding TX / RX module 16 which is part of the aforementioned unit 9.

On the basis of this regular comparison, if the current consumption detected by the meter 14 of the unit 9 is significantly equal to the consumption detected by the meter 10 of the unit 8, the control logic 15 of the said unit 9 continues to repeat and send a specific command towards the unit 8 which will cause the relative control logic 11 to keep the relay 12 of the same unit 8 in the closed state of the circuit.

In the event that there are no abusive current withdrawals, the difference between the readings reported by modules 10 and 14 will be almost nil. It should be borne in mind that this difference will never be exactly zero due to the inevitable small errors due to the tolerances of the measuring instruments.

If, on the other hand, the said control logic 15 of the unit 9 detects an appreciable inconsistency in the current values reported by the meters 10 and 14, due for example precisely to a theft of electricity carried out by the abusive user 7, the same logic of control 15 of unit 9 activates the alarm module 17 (and 27 as described below) and will execute any options set by the user, such as for example sending the command to immediately block the supply and also the interruption of the periodic command generated by the control logic of the unit 9 which has the function of keeping the relay 12 of the unit 8 in the closed state of the electrical circuit, the effect of which is in any case the immediate stop of the supply of electricity on the risers 3 and 4.

In the case of an abusive withdrawal of electricity, the difference between the values detected by meters 10 and 14 will provide an indication of how much current is (or would be in the event of immediate disconnection) subtracted and consequently also the relative amount of power expressed in watts.

The suspension of the supply can also occur in the event that anomalies are detected in the communications between the two control logics, such as the absence of readings from the meter 10.

In this case, the programming of logic 15 will notify the user of this condition and, if so set, suspend the periodic supply maintenance command with consequent disconnection of electricity supply.

In the version illustrated in Figure 4, the TX / RX transmission module 13 is shown broken down into the relative modules, the encoding / decoding module 18 of the information processed by or towards the control logic 11, a transmitter module 19 and a decoupler 20 ( mains separation filter). Unit 8 also includes a module 21 which supplies the modules present in unit 8 with low DC voltage, and the network filter 32.

The unit 9, better schematized in Figure 5, comprises, in addition to the current meter 14 and the control logic 15, a TX / RX transmission module 16 composed of an information encoding / decoding module 22, a transmitter 23 and a decoupler 24. The same unit 9 also comprises a power supply module 25, associated with a battery 26. There are also connections for interfacing with external alarms 27 (a GSM module or other), a memory module 28 for memorizing events and related electricity consumption, a display 29 to view information and events, as well as switch banks with which the user can set the preferred behavior of the control logic 15 of unit 9 in the event of theft of electrical energy carried out by the user 7. The same unit 9 also includes a push button 31 for manual reset of the supply and the mains filter 33.

Modules 21 and 25 of the respective units 8 and 9 must provide an adequate electrical power supply to the subsystems that require low DC voltage power and can also be classic "switching power supply". The voltage values supplied can be between 5 and 12 volts with the use of current absorbed by all the subsystems together which can be less than 2 amperes even in the case of the choice of making the various sections work at 5 volts, without any problems. other preferable.

The current meters of the modules 10 and 14 can also be made using the preferred conventional sensors, better of the non-invasive type, bearing in mind the measurement range which can vary according to the type of user to which one wishes to refer.

Since the readings of the current flow carried out by the modules 10 and 14 are compared by the control logic 15, the same logic can allow a weighted and appropriate tolerance, also to correctly manage various impulses and disturbances, such as to therefore allow the use of sensors of various types, such as the conventional transformer, with or without transducer, the various types of Hall effect sensors, including some hybrid versions, Rogowski coil, in general the various proximity sensors, always keeping in mind the range current within which you want to operate, which certainly can affect your preferences regarding the type of sensor to be used.

Modules 18 and 22 deal with encoding and decoding the digital information exchanged by the two control logics 11 and 15, so that any attempt to deceive the communications between units 8 and 9 to interfere with the regular operation of the system cannot have success. Although these information encoding and decoding modules are not strictly necessary for the functioning of the system and are in any case distinct from a conceptual and functional point of view, there is the possibility of integration in the control logics 11 and 15 since some microcontrollers they have sufficient power to implement their functions via software, without therefore having to resort to distinct and separate units.

The data transmission and reception modules 19 and 23 have the function of conveying the coded communications exchanged between the apparatuses by modulating a radiofrequency carrier that will transit on the electric cables 3 and 4.

Since the amount of data exchanged is very modest when compared to the capabilities achieved by the current "power-line communication" (PLC) technology, and furthermore the electrical cables in question are never filtered and report limited parasitic capacities, as well as generally having non-critical lengths, the use of current "broadband over power line" technologies such as those operating with RF carriers in the order of 2 - 30 MHz is to be considered unnecessary, although implementable. In consideration of the non-urgent needs and of limited bandwidth requests, there is a wide choice of possibilities and frequencies on which to operate, and in any case it is possible to operate using consolidated technologies, even less performing, which use transmission channels on frequencies below the MHz such as those used for data transmission on electrical networks ("narrowband PLC").

The decouplers 20 and 24 have the task of decoupling the transmission circuit from the electrical network so that the alternating current of the network does not re-enter the electrical circuits that must operate at low voltage, but at the same time allow the transit of the radio frequency modulated carrier. . The decoupling elements, generally capacitors (and inductances), are often physically constructed and integrated into the respective transmission modules.

Relay 12 is the actuator that physically allows the flow of current or interrupts it if the expected conditions occur. From the construction point of view, this device can be a conventional and reliable mechanical contactor dimensioned according to the power to be managed, more expensive and bulky, but also a solid state component (smaller and less expensive) only if they are found and can be use reliable and quality semiconductors, able to manage the currents and voltages involved, the various disturbances and impulsive transients.

The control logics 11 and 15 are substantially the programmed units which manage the system. From the hardware point of view, these logics are digital devices built around programmable "microcontrollers" which, given the wide choice, can be selected based on the performance and costs with which this invention is to be realized, since how is it possible to forego inserting some modules, such as the memory module 28 or module 29, on the other hand it is possible to add other functions thanks to the use of more powerful "microcontrollers", such as some 32-bit productions, with which performance can be extended of the system, as in the case of the graphical management of the consumption representation. Among other things, modules could be added such as the one to provide the user with audio-type report messaging.

The "microcontrollers" of the control logics 15 and 11 have a different programming, as the tasks performed are different both as regards the functions and the computational load.

It should be noted that while the "microcontroller" of the control logic 11 in the various and possible constructive declinations remains with a limited workload, the one inserted in the module 15 is more susceptible to choices aimed at offering superior performance if the device is to be built with advanced control and reporting functions to offer customers a high-value product with integrated various control functions on the use of electricity.

The related management software is loaded in the internal memory section of the microcontroller with a possible customization in case you want to create a univocal coupling of units 8 and 9. The logic 11 of unit 8 performs the function of sending to unit 9 at predetermined intervals in synchronous mode but also possibly asynchronously (but within defined time limits) the current values detected by the corresponding section 10 of the unit 8 Furthermore, this control logic 11, in regular operation (i.e. in the absence of thefts) , keeps the relay 12 in the "closed" position, that is the one in which the current can regularly flow towards the unit 9. The control logic 11 receives at regular intervals some coded signals generated by the control logic 15 which have the function of maintaining in the "closed" position the relay 12 would be disconnected from the power supply.

The power supply module 25 of the unit 9 is connected to the battery 26 which must be kept charged by the power supply itself, since even in the event of a power failure it must itself supply power to the unit 9, which in this case mode is never deactivated, and in the event of an alarm it is able to give notice.

Furthermore, the presence of the "buffer" battery 26 is also necessary to send the activation impulse to restart the supply if the user has chosen not to set the automatic reset when, after an attempted theft of electricity, there are no more abusive withdrawals, or following the suspension of the electricity supply by the supplier. Component 31 of unit 9 is just a simple button which, when pressed, causes the control logic 15 to send the coded information that reactivates the supply.

The switch 30 of unit 9 can be made with a common arrays of on / off switches that allow the user to define the behavior of the system in various situations.

In this way, in case of theft, it is possible, for example, to activate and / or deactivate the acoustic and / or light signal, or to define the system choices such as interrupting the current flow, or, in any case, given the alarm signal. , allow the supply of energy because the legitimate user considers it a priority to keep the supply of current active in their premises, although widely warned of the theft.

Furthermore, with the set of these switches the protection intervention limits can be altered, in the sense that the user could avoid the power failure if, for example, the theft is quantitatively limited, without prejudice to the alarm. Another setting is the definition of a timing that can be used in automatic attempts to reset the supply, in the sense that in order to limit the duration of disconnection of electricity, the control logic, at pre-established intervals based on these settings, automatically restarts the supply. of electricity if it no longer detects the presence of an abusive connection which is precisely explained by the inconsistent measurements of current flows.

The display 29 mounted on unit 9 is useful for reading system information, as well as alarm indications. If you decide to also insert in unit 9 a clock in which the time parameters can be set, it is also possible to report the date and time of any theft attempts.

Furthermore, on the display 29 it is also possible to report, both in numerical mode and possibly in graphic mode, the trends of the energy consumption over time, with indication of the maximum consumption peaks. With a view to reducing costs (and therefore functionality), it is also possible to use only the LED indicators to signal the various states.

The alarm module 17 is basically a light (LED) and / or acoustic signal like a common piezo buzzer which, if necessary, is driven directly by the control logic 15 in case the user chooses to activate it.

The alarm 27 of unit 9 consists of a digital output which, if theft is detected, according to the setting of the switches 30, can be placed in the "UP" state, that is with the typical value of 5 Volts, or in state "DOWN", that is to ground. This output is therefore capable of activating external alarm elements such as, for example, a GSM telephone dialer or of another type. This part is integrated in the control logic 15, even if in Figure 5 it is shown as a separate section.

The memory module 28 is an optional module, but useful if you use a display and want to represent the consumption trend. In this case the current consumption data detected by the unit 8 are stored in the memory 28 which, with a FIFO (first in first out) type management, is able to return the latest consumption values, thus being able to provide a representation consumption trends.

With the presence of the display 29, the control logic 15, again through the programming inserted, would manage the memory 28 which stores the readings on the current flow detected, thus being able to have a "history" to represent the consumption trend.

By means of the “sets” detected in the switches 30, the microcontroller of logic 15 will modify the instructions on its own behavior in the event of attempted theft, thus following the customer's instructions.

It should also be emphasized that in addition to being present, and activatable, a precise command with the immediate energy disconnection instruction given by the control logic 15 of the unit 9 if the condition of stealth electricity withdrawal is detected, the disconnection occurs automatically even if the control unit 11 of the unit 8 does not receive the periodic control and maintenance commands generated by the control logic 15 of the unit 9. Without the presence of these periodic commands, the control logic 11 of the unit 8 will never reactivate the supply.

The described operating procedure is necessary to prevent appropriate interference from disturbing the communications exchanged between unit 8 and 9 in order to cover any coded immediate "disconnection" command from unit 9, or in the worst case in which it is attempted an abusive connection by also cutting uprights 3 and 4 on the side next to the entrance to the private premises of the legitimate user.

However, this strategy makes theft impossible as unit 8 would immediately prevent the passage of electricity.

In both units 8 and 9 represented in figures 4 and 5 there are modules 32 and 33 consisting of anti-interference filters to limit possible environmental and network interference. These filters do not have a functionality linked to the internal processes of the system object of the present invention, but guarantee correct operation at the same as in particular environmental conditions, in which serious disturbances are present, for example those generated in the switching of inductive loads or by motors electrical connections (user side), or for any PLC communications of the supplier itself (electricity meter side), interference may occur in the communications between units 8 and 9.

Therefore these filters, although common and widely used, must provide for the double task of limiting both the passage of impulsive disturbances of the electricity network and any radio frequency communications, especially those coinciding with or close to the frequency of the chosen carrier on which they are conveyed. the information exchanged by units 8 and 9.

Units 8 and 9 both have two inputs and two outputs so that current flows through them. The respective logics 11 and 15 of the units 8 and 9 have a continuous exchange of information and commands, determined by the control carried out to ensure that the current flow, and therefore the relative variations, are substantially identical. When these conditions change, which happens precisely with an abusive current withdrawal, the control system of unit 9 detects the inconsistency and implements the related alarms and provisions desired by the customer. If in the event of theft the user has selected the immediate "disconnection" of the electricity supply, the same, in addition to having avoided the theft, induces the attacker to think that there is no active energy on that line of cables

Through the alarm system, the legitimate user 2 will have the opportunity, in his home, to evaluate how to intervene, and which checks to carry out, but it remains very likely that the attacker, not being able to count on that power line for an abusive connection, has desisted and / or has turned his attention to other "pillars".

Therefore, in the event of theft and if so prepared, the legitimate user will only have to press the relative reset button (if not already set automatic) which, in the absence of active abusive connections, will force the system to restart the supply.

In the event that this is not possible, it is necessary for the user to take action to search for the abusive connection, with the obvious relative removal as well as any complaint.

In any case, also considering the abusive connection and persistent theft warnings, the legitimate user can decide that in this condition the system allows the supply of current or, by still acting on the settings of module 30, allows it if the theft remains quantitatively limited to predetermined values, all with full awareness of the theft in progress.

Therefore, the device of the invention can immediately interrupt the supply of electricity, or signal the event via display, light and / or acoustic alarm, as well as other ways such as the possible connection with an external alarm device, as can be example a GSM system.

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Claims (9)

CLAIMS 1. Device for detecting and preventing theft of electricity supplied by a meter (1) to a final user (2), characterized by the fact that it includes a control logic (15) which compares the value of the current consumed by the final user ( 2) with the value of the current delivered by said meter (1). 2. Device according to claim 1, characterized by the fact that it also comprises a unit (8) located near the meter (1) and equipped with both a meter (10) for the current delivered by the aforementioned meter (1), and a logic control (11) which receives the measurement of the current detected by said meter (10). 3. Device according to claim 2, characterized in that it further comprises a unit (9) located at the end user (2) and provided with said control logic (15) which receives the measurement of the electrical energy consumption detected by said unit meter (10) (8). 4. Device according to claim 3, characterized in that said unit (9) is provided with a meter (14) suitable for detecting the measurement of the electrical energy consumption on the end user (2) and for sending the values of said measure towards the aforementioned control logic (15). 5. Device according to claim 4, characterized in that said unit (8) further comprises a TX / RX transmission module (13), a relay (12), a power supply module (21) and an anti-interference filter ( 32). 6. Device according to claim 5, characterized in that said module (13) comprises an encoding / decoding module (18), a transmission module (19) and a decoupler (20). 7. Device according to claim 6, characterized in that said unit (9) further comprises a TX / RX transmission module (16), an internal alarm module (17), a power supply module (25) connected to a battery (26), external alarms (27), a memory module (28), a display (29), banks of switches (30) and an anti-interference filter (33). 8. Device according to claim 7, characterized in that said module (16) is composed of an encoding / decoding module (22), a transmission module (23) and a decoupler (24). 9. Device according to claim 8, characterized in that said unit (9) further comprises a button (31) for resetting the relay (12) by means of said control logics (15,11).