BRPI1011107A2 - Electricity Theft System - Google Patents

Abstract

Anti-theft electric power system. The present invention relates to an electrical theft system of a registered facility, distribution branch, or distribution circuit. In the case of a registered installation, the system comprises a current source (4a) disposed immediately after the power meter (m) connected to a current handling digitizer processor - pdtc (5a); a power source (4b) disposed immediately after connecting the power cord of the registered facility to the distribution branch connected to a current handling digitizer processor (pdtc (5b); both pdtc (5a) and (5b) processors they are connected to a differential intelligent processor - pid (10a) which receives the maximum average current values resulting from these processors, pdtc (5a) and (5b), and compares them. Similarly, the invention further relates to an antitheft electrical power system of a distribution branch and a distribution circuit. The invention further relates to the assessment of the amount of electricity theft.

Description

DETAILED DESCRIPTION OF THE INVENTION FOR "ELECTRICITY ANTI-THEFT SYSTEM" The present invention relates to an electrical theft protection system, preferably based on current or temporary installation differential current picture schemes, which permit the reporting and / or prevent power theft, for example, in a registered consumer installation, a distribution branch or a distribution circuit.

Disadvantages of the prior art.

Energy meters in a registered consumer facility, such as a home, have no means of preventing theft by themselves, which are effected through total or partial deviations made before the power meter. the power cord of the registered facility, or even by tampering with the power meter, or by direct connections to the distributor branch.

In poorer regions, where there are many unregistered facilities, energy-stealing flations are visible and arranged grotesquely from the distributor branch, or from the transformer outlet or the distribution circuit, resulting in tangled chaotic and hazardous wires, as shown. in figure 4.

In the most sophisticated registered facilities, such as luxury residences, commercial and / or industrial facilities, the connection to theft takes place with more elaborate arrangements, usually not apparent, built into the masonry, which can be previously maneuvered and concealed. reading the measurement made by the employee of the distributing company.

In these types of installation, it is still possible to find parallel deviations, before the meter or the main circuit breaker, that feeds only part of the load, and then there is theft of part of the energy consumed at that moment. In this way, the power meter is always accounting for part of the load, and thus the company employee responsible for reading the meter cannot catch the power meter stopped or running if the main circuit breaker is turned off for investigation.

OBJECTIVES OF THE INVENTION

It is an object of the present invention to provide a system for the purpose of supervising, reporting, locating, curbing theft of electricity, operating at registered consumer facilities and at branch and distribution circuits. The distributing company may curb the theft by cutting off supply with a more sophisticated system or through written notification and legal action.

Other objects of the present invention are to facilitate installation at low cost and using practices that do not alter the existing and established risks in handling and living with electricity.

DESCRIPTION OF THE INVENTION The system according to the invention makes it possible to detect thefts in sophisticated elaborate or rustic arrangements as well as in distribution branches. The system according to the invention also enables the supervision of distribution circuits for a first evaluation of which extensions should receive, as a priority, the supervision in the registered consumer facilities.

Advantageously, said system is self-supervised, because in case of violation of any of its circuits, the lack of reception of any input data will generate remote alarms, informing of the occurrence of an abnormality, or will indicate the description of it, as shown. the development of HMI (human machine interaction) in the process. These alarms are also generated in cases where the sealed meter door is opened, or if another seal contact is breached. The system according to the invention is based on a differential method, applicable to any practiced theft scheme configuration, which is based on the supervision of a registered consumer installation, that is, the power leaving the distributing branch, which is The same transmitted by the power cord, disregarding small losses, should be equal to the power that goes through and out of the power meter. Otherwise there is the theft of electricity. Thus, the system checks the differential power condition primarily through the differential condition of current images from the current sources or CTs (current transformers) of the antitheft system.

Thus to avoid power theft, the solution proposed by the system according to the invention is that the power cord of the registered facility is supervised from immediately after connection to the distribution branch to immediately after the power meter. .

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in more detail below, based on the accompanying figures. Figure 1 shows a preferred perspective embodiment of the antitheft system according to the invention; Figure 2 is a three-line diagram of the preferred embodiment of the antitheft system according to the present invention; Figure 3 shows a schematic of a concentrator of an example of the preferred embodiment of the system according to the invention; Figure 4, already quoted above, shows wiring stealing energy; Figure 5 shows a scheme of CPIDs - differential intelligent processor concentrators according to the invention; Figure 6 shows a “Principle Simulator Used” simulating an energy theft at the location reported in Figures 7, 8, and 9; Figure 7 shows a report of panic signal occurrences with the address of the location of the power theft simulation occurrence; Figure 8 shows the map indicating the location of the robbery simulation site; and Figure 9 shows the aerial photo defining the location, signaled with a circle, where the power theft simulation is taking place.

DETAILED DESCRIPTION OF

INVENTION Figure 1 shows a preferred embodiment of the anti-theft system according to the invention, in a registered consumer installation (1), where the power cables (7) exit from a pole. The posts support or anchor a distribution branch (9) which is designed for a number of registered consumer facilities (1). The figure also shows the connection boxes (3A, 3B and 3C), a transformer (13) and a power consumption meter (M). Figure 2 shows a schematic of the components of the anti-theft system according to the invention in a registered consumer installation (1).

A sealed box (2) containing a power meter (M), a connection box (3A), current sources (4A) next to the meter, and a PDTC current handling digitizer processor (5A) is shown in the figure. ). Currently distribution companies require an external shelter box for the meter and the general breaker of the registered facility, as shown in figure 1, on the wall of a residence. The PDTC processor (5A) sends the resulting maximum average current values to the PID - 10A differential differential processor located in the junction box (3B), which connects the power cable (7) to the distributor branch (9). ). The values are sent to the PID processor (10A) via connecting cables (6A), but can also be sent via infrared, fiber optics, radio frequency, or any other technology, such as Bluetooth, under a protocol. RS 485 communication.

The two current values to be compared are the so-called resulting maximum average current values from a single-, two-, or three-phase circuitry coming from the current-processing digitizer processors - PDTC (5A) and (5B). Each value is the average of three average values of 64 maximum values of the current images per phase from the current sources (4A) and (4B). Communication between the PDTC (5A) and (5B) processors with the PID (10A) processor may be, for example, by wire or radio. In practice, the PDTC processor (5B) and PID processor (10A) may be together, housed in the same containment box.

In the wire connection, five wires are used for data communication, one ground wire and as many seal contacts as specified in the adopted scheme. The radio frequency connection gives the system lower cost and according to the invention requirements such as temporality and independence of the electric meter used. Processors 5A, 5B and 10A communicate via ZigBee radio frequency, checking the viewing conditions and distance between the radios.

In the system according to the invention, the PDTC processor (5A) may also be advantageously embedded in an electric energy meter (M).

It is further noted in Figure 2 that the power cable junction box (3B) contains the power supply (4B), the PDTC processor (5B) and the PID processor (10A), while the junction box (3C) ), which connects the distributor branch (9) to the transformer or distribution circuit (13), contains the current source (4C), the processed PDTC (5C) and the PID processor (10B).

Optionally, the connection boxes 3B and 3C may further contain contactors 8A and 8B respectively. If the use of this type of connection arrangement is chosen, the system according to the invention may have local or remote shutdown and reclosing of the registered consumer installation (1) or the distribution extension (13), if this is the philosophy adopted. by the distribution company at a higher cost.

In the case of supervising a registered consumer installation (1), as if isolated, the PID processor (10A) requests the maximum average current values resulting from the PDTC (5A) and (5B) processors and compares them. If there is a difference of less than a mismatch value around 3%, and adjustable, the occurrence of theft of electricity in the registered facility in focus is configured. Otherwise, the installation is normal. The PID processor (10A) always outputs the resultant maximum average current value received from the PDTC processor (5B) and, if any, also emits a radio panic signal with GPS (Global Positioning System) coupled, or by any means of communication (12), such as radio frequency, cellular telephony, fixed telephony, satellite, cable, infrared or optical fiber, to the company's server (11), which server will emit and / or receive a signal inherent to the stealth facility by locating it.

In the real case, as shown in figure 5, the differential intelligent concentrator processors - CPID (10A) with radio wave transmission are used, which aggregate and relay the information of the registered facilities to the concentrator of the distribution branch, where, pertinent information is sent by GPRS to the distribution company's server. The CPID processors (10A) aggregate the information from the registered facilities (1), whose power cables (7) emanate from the same pole or connection point from the distribution extension (9). The CPID (10A) for a registered installation (1) of a pole communicates via ZigBee radio with the CPID (10A) of the neighboring pole, and so on, toward the CPID (10B) of the transformer or distribution circuit ( 13). Then, the signal is sent to the company server (11) via any of the aforementioned means (12).

CPID concentrator processors can also be used to oversee the villas and apartment houses, shops or commercial offices.

To make the system in accordance with the most economical invention, as the registered facilities (1) are fixed references, the use of GPS will be required only for the implementation of the supervision of that registered facility (1), or the distribution extension, when, then it will be referenced to its geographical coordinate. When the referenced radio signal arrives at the company's server, from the registered facility (1), or from the distribution extension, it may generate several HMI reports as shown in figures 7, 8 and 9. In these cases, the maps and photos will then be obtained by Reverse Geocoding.

For supervision of distribution branches (9), all resulting average maximum current values from each CPID (10A) of each registered installation (1), which arrive at the PID processor (10B) of the transformer or distribution circuit (13). ) are summed and compared to the resulting maximum average current value from the PDTC processor (5C) of the currents coming from the current sources (4C), which exit the transformer or distribution circuit (13) to power the distribution branch. (9). Similarly, if there is a difference of less than a value of “Mismatch” around 3% and adjustable, the occurrence of theft of electricity in the registered facility in focus is configured. Otherwise, the distribution extension is normal.

If this abnormality is not accompanied by an abnormality in any registered facility (1), it is a sign that power is being stolen directly from the distribution branch (9), outside the registered consumer premises, which should be thoroughly inspected.

PID processors 10A and 10B may be capable of both detecting theft and automatically interrupting or reclosing the power supply, and of receiving remote commands for that purpose either from a registered facility (1). ) or a distribution extension (9), if real-time action is a company option. Of course, this is an additional cost option, but it is possible.

Conditions that configure power theft occur are sent to the company's control center (11), locating the address of the facility or extension through human-machine interactions (HMI), such as panic occurrence reports with the address of the location (figure 7), the map showing its weaponry (figure 8), and the aerial photo defining the location, signaled with a red circle, where the power theft is taking place (figure 9). The reports shown in figure 7 were obtained through the “Principle Simulator Used” (figure 6), simulating an energy theft at the location reported in figures 7, 8 and 9.

With such information, the company can take several appropriate legal actions, such as knowing about the occurrence for future action; submit a monthly consumable account calculated by "passport" with the reports and aerial photo locating the address of the theft; go to the place with legal apparatus to set up lost revenue; or, if applicable, install a remote drive that acts on a contactor to cut off the power supply when theft occurs.

Locally, there may also be a visual or audible signal indicating that there was an abnormality, placing the perpetrator of a power theft in a registered facility (1) or, especially, at the distributing branch (9), in an awkward situation, as well as warning that this action is being reported and observed, which certainly discourages theft.

If the theft occurs in a registered consumer facility (1), the person responsible for the theft must be notified of this occurrence. When theft is occurring at a distribution branch (9) through an unregistered facility, consumers of that branch's registered facility (1) should be informed in their consumption accounts of the possibility of potential power outages due to theft. in the neighborhood, which discourages the practice of theft, preventing this practice from spreading through the neighborhood, usually by offering services to bad professionals.

Additionally, the system according to the invention may allow, via software, to "estimate" supervise the energy meter (M) in order to determine whether it is being rudely tampered with. This supervision is done by means of the arithmetic average of four resulting maximum average current values within one hour and is called the maximum current current hour. The latter value multiplied by the CT or current source transformation ratio, by λ / 2/2, by 0.91, by the number of meter phases (M), and by the minimum value of the power factor allowed by the distributor, 0.92 or 0.85, we have the value of Wh at the time considered. Adding these values over the entire time range of the reading to be compared gives the estimated consumption value. Assuming an error of X%, which the practice will indicate which will be, we have the consumption value for comparison. If the consumption reading is less than this consumption value for comparison, it is probably a meter to check if it is grossly adulterated.

Finally, if the distribution company wishes to supervise distribution circuits, in order to identify which distribution extensions should receive, as a matter of priority, the supervision of the registered facilities, this service will be carried out in a similar manner to the supervision of extensions. The maximum average currents resulting from the PDTC processors (5C) of each distribution extension (9) are sent via GPRS from the respective PID processor (10B) to be added to the other maximum average currents resulting from the other extensions that make up the distribution circuit. (13). This sum is compared to the maximum average current resulting from the circuit greater than this. If there is a difference of less than a value of “Mismateh” around 3%, and adjustable, the occurrence of electricity theft in the registered facility in focus is configured. Otherwise, the installation has nonnality. The present invention is not limited to the embodiments described above and is therefore applicable to other alternatives of use. For example, the system according to the invention may further assess the amount of theft practiced more accurately. This will require the inclusion of voltage sources in the PDTC processors (5B and 5C). If a voltage source is included in the PDTC processors, the system can turn power differential.

Accordingly, the present invention should be considered broadly based on the appended claims.

Claims (15)

1. Anti-theft electricity system of a registered installation, characterized in that it comprises a current source (4A) disposed immediately after an electricity consumption meter (M); a current handling digitizer processor - PDTC (5A) that treats current images from the current source (4A); a power source (4B) arranged precisely at the connection of the power cable (7) to a distribution branch (9); a -PDTC current handling digitizer processor (5B) which treats current images from current source (4B); and a differential intelligent processor - PID (10A) which receives the maximum average current values resulting from processors PDTC (5A) and (5B) and compares them. Anti-theft electric power system according to claim 1, characterized in that the values to be compared by the PDTC processors (5A) and (5B) are the average of three average values of 64 maximum values per phase of the images. current sources from current sources 4A and 4B. Electricity anti-theft system according to claim 2, characterized in that as a current value for differential comparison, such as the resulting maximum average current, any mode that associates a scalar or numerical value in exchange with a vector value in order to provide a comparison between these values. Anti-theft electric power system according to claim 1 or 2, characterized in that in the comparison between the resulting maximum average current values from the PDTC (5A) and (5B) processors, carried out by the PID (10A) processor having a differential value, less than an adjustable 3% mismatch value, sets up electric theft. Anti-theft electric power system according to one of Claims 1 to 4, characterized in that the resulting maximum average current values are sent to the PID processor (10A) via infrared connection cables (6A) , optical fiber or radio frequency or any other means of communication. Anti-theft power system according to one of Claims 1 to 4, characterized in that upon detection of a value above mismatch, the CPID processor (10A) emits a panic signal to the other radio or server. (11) by means of communication (12). Anti-theft electric power system according to claim 5, characterized in that the means of communication (12) is radio frequency coupled with GPS (Global Positioning System) coupled function, or GPRS type telephony, fixed telephony , satellite, cable, infrared or fiber optic. 8. Distribution branch antitheft system, characterized in that it comprises a current handling digitizer processor - PDTC (5C), with a current source (5C), and a differential intelligent PID processor (10B) of the transformer or distribution circuit (13), and all the maximum average current values resulting from each registered installation (1), which reach the PID processor (10B) via ZigBee communication, are summed and compared with the average current value. maximum resulting from the PDTC processor (5C), derived from the values coming from the current sources (4C), corresponding to the images of said currents leaving the transformer or distribution circuit (13) to supply the distribution branch (9). Anti-theft electric power system according to claim 8, characterized in that in the comparison between the resulting maximum average currents made by the PID processor (10B), a differential value, less than a mismatch value of 3%, adjustable, sets up electrical theft at distribution branch. 10. A distribution circuit antitheft system, characterized in that it comprises digitizing current handling processors - PDTC (5C), with a current source (5C), and an intelligent PID differential processor 10B (10B). transformer or distribution circuit (13), and the maximum average currents resulting from the respective PDTC processors (5C) from each distribution branch (9) are sent via GPRS from the respective PID processor (10B) to be added to the other maximum average currents resulting from the other branches that make up the distribution circuit (13), and this sum is compared with the maximum average current resulting from the circuit greater than this one. Anti-theft electric power system according to claim 10, characterized in that in the comparison between the sum of the sum of the maximum average currents resulting from the other branches and the value of the maximum average current resulting from the upper circuit, there is a differential value. , by means of an adjustable mismatch value of 3%, sets up electrical theft at the distribution branch. Electricity theft system according to one of Claims 1 to 11, characterized in that the current source (4B), the PDTC processor (5B) and the PID processor (10A) are arranged in a terminal box. (3B); and the power supply (4C), the PDTC processor (5C) and the PID processor (10B) are arranged in another junction box (3C), said boxes (3B, 3C) being powered by the distributor branch (9), and may contain, respectively, contactors (8A) and (8B). Electricity theft system according to one of Claims 1 to 12, characterized in that the PID processors (10A) and (10B) can detect theft and interrupt / reconnect the power supply. Anti-theft electrical system according to claim 13, characterized in that the interruption / reclosing of a registered installation (1) or a distribution branch (9) occurs by means of remote commands received by PID (10A ) and / or (10B). Electricity theft system according to one of Claims 1 to 14, characterized in that it can assess the amount of theft committed.