ES2731672B2 - DETECTION METHOD OF FRAUDULENT HANDLING IN THE TERMINAL OF ELECTRICAL ENERGY METERS - Google Patents

Description

D E S C R I P T I O N

FRAUDULENT HANDLING DETECTION METHOD AT THE TERMINAL

OF ELECTRICAL ENERGY METERS

OBJECT OF THE INVENTION

The main object of the present invention is a method that makes it possible to detect fraud in single-phase or three-phase electrical meters, whether conventional (induction disk) or digital.

Specifically, the fraud that can be detected with the proposed method is the manipulation of the connections of the conductors coming from the network and charging the terminal block of the meter. The method can be carried out without removing the terminal cover.

The method is based on the measurement of the magnetic flux density or magnetic field in a certain area of the front surface of the meter. From this measure, the values of some indicators are calculated that make it possible to determine whether the meter has been manipulated or not.

BACKGROUND OF THE INVENTION

The single-phase meters of the state of the art comprise a fixed part and a terminal cover, joined together by screws. The terminal cover is removed to connect the ends of the phase and neutral conductors on the mains side to the meter with the respective phase and neutral conductors on the load side. Inside the single-phase meter there are basically an amperometric circuit, a voltometric circuit and a terminal block for connection to the network and the load.

In three-phase meters the scheme is similar, but with two additional phase conductors both on the grid side and on the load side, so it has not been considered necessary to represent it graphically.

There are various methods to fraudulently reduce the measurement of electrical energy consumption in electrical meters. One of them, regularly employed, consists of manipulating the terminal block connections. To do this, the fraudster breaks the seal and, using a screwdriver, loosens the screwdriver of the terminal cover, allowing its removal to access the terminal block.

There are two possibilities to manipulate the connections. The first option, from now on type 1 fraud, consists of bridging the terminals corresponding to the amperometric circuit. For example, a fraudulent electrical connection can be added between a grid connection terminal and a load connection terminal. This allows a path parallel to the original to be established to reduce the current through the amperometric circuit and therefore the energy measured by the meter.

In the case of three-phase meters, type 1 fraud admits variants, such as inserting a direct fraudulent connection between the network and load connections of any one of the three phases, inserting two direct fraudulent connections between two of the three phases, or inserting three fraudulent connections , one per phase.

The second option, from now on type 2 fraud, consists of opening the voltmeter circuit. This is achieved by disconnecting the network conductors and their corresponding of equal voltage on the load side from the terminal block and connecting them directly to each other.

Either of these two types of fraud is visually detected by opening the terminal cover, but it is an invasive method. Currently, with the installation of remote-managed digital meters, face-to-face inspection is not as common as with induction meters since periodic energy consumption can be remotely measured. That is why remote fraud detection methods are currently being developed.

A first known method of remote detection of fraud is the analysis of the evolution of consumption over time. With this detection method, type 2 fraud is more easily detected. This is because, in type 1 fraud, the meter marks a certain consumption below normal. Said consumption registered by the meter depends on the resistance of the conductor or conductors that make up the connection that has been bridged and above all on the contact resistance of the ends of said connection to the terminals in which it has been connected.

However, in type 2 fraud, consumption is zero during the period of time that the fraud lasts. Both in the conventional meter (manual reading) and in the remote-managed one, a zero consumption for months is easily detectable by the distribution companies by comparing it with the consumption of the same subscriber in past periods.

However, type 2 fraud is generally practiced for short periods of time, precisely to avoid detection by power companies. Thus, the result in consumption during the charging period can be similar to that generated with type 1 fraud.

Regardless of the type of fraud, this detection method presents as major associated problems the fact that it is necessary to have, depending on the percentage of defrauded energy, a certain number of months of fraud-free consumption for each subscriber. These data are necessary to know the typical consumption of the subscriber and it is also necessary to assume that said subscriber has consumption habits that do not change substantially. Another disadvantage of this method is that it is based on statistical calculations that are associated with a certain percentage of errors in the predictions.

In the state of the art, other methods are known to detect both type 1 and type 2 fraud. For example, to detect type 1 fraud a method is known based on the use of an intensity sensor arranged inside the meter, which it measures the current through the amperometric circuit, and another intensity sensor arranged outside, at the connection point. The internal sensor measurement is sent as a communication channel through the connection cable itself to the external sensor and they are compared, detecting possible fraud if both measurements are different.

Regarding type 2 fraud, a method applicable to induction meters is known, based on the insertion of a Hall effect sensor in the coil of the voltmeter circuit and another in the amperometric circuit. In this way, if the voltmeter circuit is opened, the Hall sensor of the voltmeter coil measures a null field and that of the ammeter does not, thus detecting fraud. With current digital meters, type 2 fraud is very easy to detect since the voltage indicated by the meter is zero.

Another known solution that tries to avoid fraud in the manipulation of the terminal block is the detection of the removal of the terminal cover by means of a small switch that changes state and generates an alarm signal when this occurs.

A method of detecting the presence of magnetic field sources external to the meter (such as magnets, coils, etc.) that have been placed in such a way as to affect the correct operation of the meter is also known from the state of the art. To do this, magnetic field sensors are used located inside the meter that provide information on external magnetic fields that are interfering with the meter.

DESCRIPTION OF THE INVENTION

The method of detecting fraudulent tampering in the electrical energy meter terminal block of the present invention allows the detection to be carried out without having to open the meter, quickly and reliably.

In electric meters, for example single-phase, the line-side phase conductors and line-side neutral are connected respectively with the load-side phase conductors and load-side neutral through a terminal block housed inside the meter. The electric current that enters through the mains side phase conductor connection terminal towards the amperometric circuit exits through the load side phase conductor connection terminal. The same current returns from the neutral conductor on the mains side from the neutral on the load side. Regardless of the meter (induction or digital, magnetically shielded or not), the currents through the four conductors (in the case of a single-phase meter) generate, at a point outside the meter, a vector magnetic field that is distributed in all directions .

The vector magnetic field at any point outside the counter is defined by three Cartesian components. This distribution can be characterized by a magnetic field detector device, arranged outside the meter. The fraudulent insertion between the connections of the network phase and the load phase (fraud type 1) causes the appearance of a current that does not enter the meter and that generates a magnetic field that is superimposed on the existing field. If the new distribution is compared with the original distribution by means of one or more indicators such as the variation of one of the fields along a line or a ratio between two of the fields at a certain point, it is possible to detect fraud if said change is appreciable enough not to be attributed to measurement errors, external interference or any other cause other than the fraud itself.

Thanks to this method, the detection does not require the removal of the terminal cover, thus speeding up the inspection of the meters by the staff and reducing the cost that the face-to-face detection of fraud currently entails for distribution companies.

This method can also be used to detect type 2 fraud. When the mains neutral and load neutral conductors are disconnected from the terminal block and connected directly to each other, the spatial structure changes the magnetic field and this change can be detected from the same way off the counter.

Depending on the power consumed by the load, the components of the magnetic field outside the meter have different magnitudes, so it is necessary for the correct execution of the method to determine indicators that are sufficiently invariant compared to the value of the current that the meter has in each moment. To ensure the correct choice of indicators, it is necessary to locate a set of points whose field components vary in the same way. Preferably points will be chosen whose components vary predominantly linearly with the current.

If these points are located above the terminal cover of the meter and at a certain distance from the magnetic screens that eventually protect the amperometric and voltometric circuits, the variation of the field with the current is substantially linear. Additionally, sufficiently safe thresholds can be defined to take into account the possible contributions that may affect this ideal behavior (interferences from adjacent counters, measurement errors, non-linear field variation, etc.).

For each type of single-phase meter, a preliminary study must be carried out in order to set the measurement points and the measurement magnitudes at each point.

The greatest advantage of the present invention over previously proposed methods is that it avoids making internal modifications to the meter since detection is This is done by means of portable external devices arranged close enough to the meter. This fact greatly facilitates the application of the method and increases its versatility since it can be used in meter models from different manufacturers.

The only thing necessary is to bring the measuring device closer to the front surface of the meter to capture a sufficient field value generated by said meter. That is, it is necessary to avoid the unwanted effects of interference caused by other counters or neighboring elements. Therefore, it is necessary to previously disassemble any protective enclosure against direct contacts.

DESCRIPTION OF THE DRAWINGS

To complement the description that is being made and with the aim of helping a better understanding of the characteristics of the invention, according to a preferred example of a practical embodiment thereof, a set of drawings is attached as an integral part of said description. where for illustrative and non-limiting purposes, the following has been represented:

Figure 1a.- Shows a front view of a single-phase meter.

Figure 1b.- Shows a view of the single-phase meter of figure 1a in which the internal elements have been represented.

Figure 2.- Shows a perspective view of a meter that is being manipulated, with the seal already broken.

Figure 3a.- Shows a terminal block with a manipulation of connections corresponding to a type 1 fraud.

Figure 3b.- Shows a terminal block with a manipulation of connections corresponding to a type 2 fraud.

Figure 4.- Shows a meter without the terminal cover and with the representation of the magnetic field generated when the meter has not been manipulated.

Figure 5a.- Shows a meter like the one in figure 4 that has been manipulated with a type 1 fraud.

Figure 5b.- Shows a meter like the one in figure 4 that has been manipulated with a type 2 fraud.

Figure 6.- Shows a front view and a side view of a CERM1 single-phase meter.

Figure 7.- Shows a view of the single-phase meter CERM1 of figure 6 in which the position of the measurement points for the detection of tampering according to the method of the present invention is shown.

PREFERRED EMBODIMENT OF THE INVENTION

Hereinafter, some embodiments of the invention are described with the aid of FIGS. 1 to 7.

As previously described, fraudulent manipulations that are carried out in meters, both single-phase and three-phase, can be grouped into two types. To better understand how these manipulations are carried out, a meter, in this case single-phase, has been represented in Figures 1a and 1b, and its essential elements have been indicated.

As can be seen in figure 1a, the exterior of the meter is protected by a fixed part (1) that also allows it to be anchored to the wall or to the place where it is to be installed, and by a terminal cover (2) that It is removable and is attached to the fixed part (1) by screws (3). You can also see the connection cables on the mains side, more specifically the phase conductor on the mains side (LR) and the neutral conductor on the mains side (NR), and the connection cables on the load side, more specifically the phase conductor on the mains side. load (LC) and the neutral conductor on the load side (NC).

Figure 1b shows the elements that are housed in the fixed part (1), such as the amperometric circuit (4), the voltometric circuit (5) and the terminal block (6). On the terminal block (6) the connection terminal of the line-side phase conductor (B1), the connection terminal of the load-side phase conductor (B2), the connection terminal of the mains side neutral conductor (B3) and the load side neutral conductor connection terminal (B4).

In three-phase meters the scheme is similar, but with two additional phase conductors both on the network side (L1R, L2R, L3R) and on the load side (L1C, L2C, L3C), so it is not necessary to represent it graphically.

Figure 2 shows a counter being manipulated. As you can see, the meters have a seal (7) that allows to physically detect if there has been a manipulation. In this case, you can see how, to unscrew the screw (3) that allows removing the terminal cover (2) to access the terminal block (6), the seal (7) must be broken.

Likewise, figures 3a and 3b show types 1 and 2 of fraud, respectively, which have been previously described. Fraud type 1, observable in figure 3a, consists of bridging the terminals of the amperometric circuit by adding a fraudulent electrical connection (8) between the connection terminal of the line-side phase conductor (B ¹ ) and the connection terminal of the load-side phase conductor (B ² ) creating a path parallel to the established one.

Fraud type 2, observable in figure 3b, is carried out by disconnecting the connection terminal of the mains-side neutral conductor (B ³ ) and the connection terminal of the load-side neutral conductor (B ⁴ ), connecting them directly to each other by means of the fraudulent connection (9).

Figure 4 shows the magnetic field generated when the connections are arranged correctly. Point P is the point chosen for data collection of the magnetic field. As can be seen in said figure, at point P a magnetic field can be measured with an effective value of the specific magnetic field ( B P) and which is defined by the three Cartesian components corresponding to the x axis, the y axis and the axis z ( B Px, B Py, B Pz). This distribution is characterized by a magnetic field detection device at the point P of interest.

If point P is located above the terminal cover (2) and as close to it, the field that is detected is mainly due to sections 10-11 (connection of the mains side phase conductor to the Bi-connection terminal of the neutral conductor mains side to terminal B3) of conductors LR-NR and 12-13 (connection of the load-side phase conductor (LC) to terminal B2- connection of the load-side neutral conductor (NC) to terminal B4) of LC-NC conductors. These sections are separated from each other (eliminating the multipolar cable cover that can be seen in figure 7) for their connection to terminals B1, B2, B3 and B4.

The fraudulent insertion of the connection between the network phase conductor and the load phase conductor (8) in the amperometric circuit (fraud type 1, figure 2a), causes the appearance of a current Id that does not enter the meter, as is seen in figure 5a. Said current Id generates a magnetic field that is superimposed on the existing field, as can be seen in the figure.

In an exemplary embodiment, the Bpz field and / or the Bpy / Bpz ratio at a certain point can be taken as indicators of the magnetic field at P. The variation of these indicators allows to determine if there has been a fraudulent manipulation.

Figure 5b shows the variations that a type 2 fraudulent manipulation originates at point P. In this case, when the neutral conductor of the network and the neutral load conductor are connected together, a change in the magnetic field is caused which also affects the magnetic field at P.

The preferred embodiment of the invention is aimed at detecting the manipulation of CERM1 type meters as shown in figure 6. It is simply a particular embodiment, especially interesting in countries like Spain because CERM1 type meters are one of the most widely used Therefore, it should not be understood as a limiting example of the application of the invention. The method of the invention can be used with other types of commercially used single-phase meters, for three-phase meters or even for CERM1 meters with design variants.

The magnetic field measurements are carried out, according to the method of the present invention, in the same way at each point Py ... Pn aligned with each other, located as close as possible to the plane nt shown in figure 7. The plane nt is a plane that passes through the centers of all the terminals (B1-B4) of the meter, and is perpendicular to a plane n0 that contains the rear surface (14) of the meter. The exact points P ^ —Pn at which the measurements are made will depend on the skill of the operator and the greater or lesser difficulty of positioning the magnetic field measurement device (17) depending on its own characteristics (weight, geometry, size, etc.).

Furthermore, the points P ^ —Pn are arranged as close as possible to the front surface (21) of the terminal cover (2) according to the restrictions imposed by the magnetic field measuring device (17). More specifically, these limitations are related to the position of a sensor element (18) housed in the measuring device (17) at a certain distance from the surface of the meter (20). Said surface of the meter (20) is located, in order to carry out the measurements, in contact with the front surface (21) of the terminal cover (2) of the meter as shown in the aforementioned figure 7. The measurement of the magnetic field depends also of a measurement axis (19) of the magnetic field of the sensor element (18) that is also shown in the figure and whose position depends on the geometries of the cover (2) (on which the measurement device (17) rests )) and the measuring device itself (17).

Other elements that have been represented in figure 7 are a first hole (16) arranged in the terminal cover (2) destined to receive the screw (3) and a second hole (15) arranged in the fixed part (1) in the that houses the end of the screw.

As can be seen in figure 7, in the CERM1 counter, the screw (3) is housed in the second hole (15) that is aligned with the four terminals (B1-B4) and extends perpendicularly to the first hole (16 ). Thus, said first hole (16) can be chosen, as in figure 7, as the measurement point P. It is a point easily identifiable by any operator and which is in a centered position with respect to the terminal block (6).

The method of the present invention comprises a step of choosing, preferably, said second hole (16) as point P ^{^ i ^} , choosing n odd. By

On the other hand, the point Pí is chosen at a distance from the point P ^ w + i ^ somewhat greater than

distance between terminal B1 and the second hole (15). In an embodiment in where the total width of the counter is 125 mm, the distance between Pt and P n ^ + ^ is

about 5 mm more than the distance between Bi and the hole (15).

In the same way, the opposite point Pn has to be at a distance from the point P n ^ + ^ something

higher than that between terminal B4 and the second hole (15). In a 125 mm counter like the one previously used, this distance would also be, for example, about 5 mm more than the distance between Pn and the hole (15). The remaining points are equidistant and separated from each other by a certain distance. In an exemplary embodiment such as the one being proposed, said distance would be, for example, about 7 mm.

y Pn es superior a la separación entre los bornes del contador más alejados entre sí.Preferably, the spacing between the points

and Pn is greater than the separation between the terminals of the meter furthest from each other.

In the embodiment that is presented, a sample is taken at 11 points, that is, «= 11. The magnetic field to be measured is directed substantially in the direction perpendicular to the plane ^ 0, and may vary slightly to facilitate the measurement process, as can be seen in figure 7, where the measurement axis (19) is perpendicular to the front surface (20) of the terminal cover (2). To avoid the effect of the Earth's magnetic field, the magnetic field measuring device (17) used for the method must measure only fields generated by alternating current and have internal signal processing to obtain the effective value Bp-í Bpn at each point P! _Pn.

The following preferred indicators are established below to detect fraud in the manipulation of connections:

- Indicator

- Indicator

According to the method of the present invention, it can be guaranteed with a 100% probability that there is a fraud (type 1 or type 2) if one of these two criteria is met:

1) If it is true that / i <0.5

2) If 0.5 < I1 <6, 5 // 2 and I2 < 6 are satisfied simultaneously, there is fraud with a probability of 100%.

If none of the criteria is met, it can be ensured that there is no fraud with a high probability, between 50% and 100%.

Claims (11)

1. - Method of detecting fraudulent manipulation in the terminal block of electricity meters that comprise a fixed part (1), with a rear surface (14), and a terminal cover (2), with a front surface (21), said terminal cover (2) removably attached to the fixed part (1) by means of screws (3) and a plurality of terminals (B1, B2, B3, B4) destined to receive connections phase of the network (LR), neutral of network (NR), load phase (LC) and load neutral (NC), and which is characterized by comprising the following stages: - determining a reference point P outside the meter; - measure the magnetic field and its components at a plurality of n points P ± ... Pn, among which is the point P, located above the terminal cover (2) with the meter closed and in which the field components magnetic vary in the same way depending on the electrical energy in the meter; - obtain at least one indicator ( l1,1 2) corresponding to a combination of magnetic field values obtained at at least two of the points P ± ... P n; - determine, based on the value of at least one indicator (/ x, / 2), the presence or absence of magnetic fields generated by the modification of any of the terminal connections (B1, B2, B3, B4) of the meter. 2. - Method according to claim 1 characterized in that point P is chosen in a position as close as possible to the front surface (21) of the terminal cover (2) of the meter. 3. - Method according to claim 1 characterized in that the step of measuring the magnetic field is carried out uniaxially according to a direction perpendicular to the front surface (21) of the terminal cover (2) of the meter. 4. - Method according to claim 1 characterized in that the plurality of n points P1 ... Pn are selected aligned with each other as close as possible to the intersection between the front surface (21) of the terminal cover (2) and a plane n1 that passes through the centers of the terminals (B1-B4) of the meter and is perpendicular to a plane n0 that contains a rear surface (14) of the fixed part (1) of the meter. 5. - Method according to claim 1 characterized in that the separation between the points?! and Pn is greater than the separation between the terminals of the meter furthest from each other. 6. - Method according to claim 1 characterized in that the magnetic field measurement at points ... Pn is the effective value BPl B Pn. 7. - Method according to claim 6 characterized in that the at least one indicator ( I1) is obtained according to the following equation:

8. - Method according to claim 7 characterized in that the step of determining the presence or absence of magnetic fields generated by modifying any of the terminal connections (Bi, B2, B3, B4) of the meter is carried out taking into account the Indicator value ( I1) such that if <0.5 is true, it is determined that there is the presence of these magnetic fields. 9. - Method according to claim 6 characterized in that the at least one indicator (/ 2) is obtained according to the following equation: } _ ma x [BPl, ..., BPn] 2 mm [BPl, ..., BPn] 10. - Method according to claims 7 and 9 characterized in that the step of determining the presence or absence of magnetic fields generated by modifying any of the terminal connections (Bi, B2, B3, B4) of the meter is carried out taking into account It takes into account the value of the indicators (/ x) and (/ 2) such that if 0.5 <<6.5 / I2 and I2 < 6 are satisfied simultaneously, it is determined that there is the presence of said magnetic fields. 11. - Method according to claims 7 and 9 characterized in that the step of determining the presence or absence of magnetic fields generated by the modification of any of the terminal connections (B1, B2, B3, B4) of the meter is carried out taking into account counts the value of the indicators ( I1) and (/ 2) such that if> 0.5 and it does not hold simultaneously that 0.5 <Ii <6.5> /! 2 and that I2 <6 it is determined that there is presence of said magnetic fields, the probability of absence being less than 100% but greater than 50%.