WO2012175762A1

WO2012175762A1 - Method and device for protecting runs of electrical conductors

Info

Publication number: WO2012175762A1
Application number: PCT/ES2012/000152
Authority: WO
Inventors: Germán HORMAZA VILLELABEITIA; Francisco Miguel NIETO MONTESANO; Javier NARVÁEZ RIARÁN; Juan Carlos PEÑAS MANRIQUE; José Antonio HORTAL CARRETERO
Original assignee: Iberwave Ingenieria Sll
Priority date: 2011-06-20
Filing date: 2012-05-31
Publication date: 2012-12-27
Also published as: ES2397584B1; ES2397584A1

Abstract

The invention relates to a method and device for protecting runs of electrical conductors. The method comprises a time-delay period and a verification period, which take place sequentially. The time-delay period in turn comprises the injection at one end of the electrical conductor of an encoded, modulated radio-frequency signal in order to: transmit at least one unique identifier; transmit the radio-frequency signal through the conductor; and receive, demodulate and decode said radio frequency signal in a head-end sensor at the other end of the run. The verification period comprises the comparison, in the head-end sensor, of the at least one unique identifier received with an internal list of unique identifiers. In the absence of the at least one unique identifier in the head end, an alarm status is generated. The method is suitable for multi-wire electrical conductors.

Description

PROCEDURE AND DEVICE FOR PROTECTION OF TRENDS IN

ELECTRIC CONDUCTORS

Field of the Invention

The present invention relates generally to the field of protection of electric conductor lines against theft, such as for example copper wire lines.

Background of the invention

The increase in world demand, compared to a stabilized copper production, has led to a rapid increase in the price of this material in recent years. As a consequence, a parallel market for stolen cable has been developed. Theft of copper has become a very important economic problem, since the price of the material removed is added to the problems derived, such as the cut of supply, the impossibility of providing certain services (railroads, irrigation), problems of electrical safety derived, and the damages caused to associated systems or machinery.

Copper cable subtraction occurs routinely in remote locations, as a natural way to minimize the risks by the perpetrators of the theft. Various automatic surveillance methods have been proposed in the prior art for such installations, such as motion detection, camera surveillance and perimeter protection. In all cases, the solution presents obvious practical problems due to the special characteristics of the object to be protected. Among the fundamental problems of these proposed solutions can be mentioned false positives due to the presence of animals or rain, and the economic impossibility of monitoring long copper lines.

Another category of protection systems is based on the sending of a continuous or alternating low frequency voltage, so that the cut of the cable prior to the subtraction generates the interruption of the electrical circuit, detecting said interruption to generate an alarm. This solution mainly presents two types of problems. On the one hand it cannot be applied when the conductor is in operation (that is, when voltage is applied to the power supply), and on the other hand it does not fit wiring structures complex (as connected in tree, or star).

US patent application US 2010/0085189 A1 intends to partially solve the drawbacks of the prior art, disclosing a method such as that described above, which also inserts a low voltage in the electrical circuit when said conductor is not in operation. However, this method still does not adapt to complex wiring structures.

In addition, the known systems described above do not provide sufficiently high levels of protection required in the field of power lines, and more specifically in the protection of copper lines.

On the other hand, no system is known in the art that allows to reliably detect the cutting and subtraction of a single wire from an electric conductor consisting of several wires, such as for example the five-wire copper electrical conductors commonly used.

Therefore, there is currently a need in the market for a procedure and device for protection of laying of simple and inexpensive electrical conductors, which provide reliable and safe protection thereof and at the same time are applicable to complex wiring structures. It would also be desirable to have a procedure and device to detect the cutting of a single wire of an electrical conductor consisting of several wires.

Summary of the invention

The present invention relates to a method and a device for protection of laying of electrical conductors, in order to generate an alarm when the interruption of the integrity of the circuit is detected.

According to a first aspect of the present invention, the method comprises sequentially:

- a timing period comprising:

or injecting at one end of the electrical conductor by means of a terminator sensor a radiofrequency signal, modulated and encoded to transmit at least one unique identifier;

or transmitting said radiofrequency signal by said electrical conductor; or receive, demodulate and decode said radio frequency signal at a header sensor at the other end of the line; Y

- a verification period comprising:

or compare in the header sensor the at least one unique identifier received with an internal list of unique identifiers;

In addition, the method comprises generating a driver cut-off alarm state in the absence of the at least one unique identifier in the header sensor of the laying, since said absence of the at least one unique identifier implies the subtraction of the physical medium by the that the radio frequency signal is propagated (that is, the electrical conductor).

According to a second aspect of the present invention, a method is provided that allows the detection of the subtraction of a single wire from an electrical conductor consisting of a multitude of wires. For this, the method according to the second aspect of the present invention comprises, in addition to the steps of the first aspect process, the additional steps of

- measure electrical parameters of the laying on the terminator sensor;

- including said electrical parameters measured in the radio frequency signal transmitted by said electrical conductor;

- measure the same electrical parameters of the laying in the header;

- compare, in the header, the electrical parameters measured in the terminator sensor with the electrical parameters measured in the header; Y

- generate a cut-off alarm state of at least one wire in case the electrical parameters measured in the terminator sensor and the electrical parameters measured in the header do not match.

In fact, the electrical parameters of the conductor to be protected, such as, for example, voltage, current, impedance, etc., vary depending on the number of wires that constitute said electrical conductor. Therefore, if one of these wires is subtracted along a multi-wire electrical conductor (for example a typical five-wire copper conductor), the electrical parameters measured at one end of the electrical conductor will be different from those measured in the another end, therefore the absence of said conductor wire can be detected even though the radio frequency signal between both ends of the electrical conductor can still be transmitted. For its part, the device of the present invention, suitable for practicing the procedure described above, comprises, according to a first aspect of the invention:

- at least one terminator sensor arranged to inject a radio frequency signal into at least one electrical conductor to be protected, modulated and encoded to transmit at least one unique identifier;

- a header sensor arranged to receive, demodulate and decode said radio frequency signal; Y

- an internal list of unique identifiers with which to compare the at least one unique identifier transmitted in said radio frequency signal.

As explained above, the header sensor is arranged to generate an alarm state in the absence of at least one unique identifier in the header.

According to the second aspect of the invention, the device is adapted to implement the method according to the second aspect of the present invention, detecting the subtraction of a single wire from an electrical conductor comprising a multitude of wires, for which the sensor The terminator is also arranged to measure electrical parameters and include them in the radio frequency signal transmitted by said electrical conductor. The header sensor is in turn arranged to measure the same electrical parameters and compare them with the electrical parameters transmitted from the terminator sensor; so that a cut-off alarm state of at least one wire can be generated in the header sensor in case the electrical parameters measured in the terminator sensor and the electrical parameters measured in the header do not match.

It is therefore understood that, as will be further described hereinbelow, the present invention provides a method and a device for protecting highly reliable electrical conductor lines and allowing their application to complex wiring structures. In fact, in the case of more complex structures, as many terminator sensors as necessary will be included, each providing a radio frequency signal comprising at least one unique identifier. These radio frequency signals are received in a single header and, in the absence of a specific unique identifier, may determine exactly which section of electrical conductor is being subtracted.

On the other hand, the elements connected to the low-voltage electrical network, as well as the characteristics of the transmitted signal, allow operation under all conditions of the laying of electrical conductors that are intended to be protected. That is, the method and device of the present invention will work both with applied voltage and in the event that the line has been temporarily disconnected from the general mains (for example during the day on driving lines for street lighting street lamps) ).

Spanish patent application no. 201 100718, whose priority is claimed in this patent, refers to a process according to claim 1 of this patent; claim that is identical to claim 1 of the priority Spanish patent application, no. 201 100718, with the exception of the modifications derived from the fact that the term "header (3)" in said priority Spanish patent application has been replaced in this patent by the term "header sensor (3)", with the same meaning, since this is now required for reasons of clarity, since, if in Spanish patent application no. 201 100718 there was only one type of sensor in the header, in the object of this patent there may also be at least one "multinode sensor (4)", also located in the header. Spanish patent application no. 201 100718 also refers to a device according to claim 15 of this patent, identical to claim 1 1 of Spanish patent application no. 201 100718 with the same proviso, which does not affect the content or scope of the claim, that the term "header (3)" in the previous patent application has the same scope as the term "header sensor (3)" in this patent.

Brief description of the drawings

The present invention will be better understood with reference to the following drawings illustrating preferred embodiments of the invention, provided by way of example, and which should not be construed as limiting the invention in any way.

Figure 1 shows a flow chart representing the process according to the preferred embodiment of the first aspect of the present invention.

Figure 2 shows a flow chart representing the process according to the preferred embodiment of the second aspect of the present invention. Figure 3 shows a block diagram according to the preferred embodiment of the method of the second aspect of the present invention.

Figure 4 shows the internal block structure of the head sensor of the protection device according to the preferred embodiment of the present invention.

Figure 5 shows the internal block structure of the terminator sensor of the protection device according to the preferred embodiment of the present invention.

Figure 6 shows the internal block structure of the multinode sensor of the protection device according to the preferred embodiment of the present invention.

Figure 7 shows the complete structure of the operation of the process according to a first embodiment of the present invention.

Figure 8 shows the complete structure of the operation of the process according to a second embodiment of the present invention.

Detailed description of the preferred embodiments

As can be seen in the flow chart shown in Figure 1, the method of protection of laying of electrical conductors according to the first aspect of the present invention comprises sequentially:

- a timing period that includes:

or transmitting said radiofrequency signal by said electrical conductor;

or receive, demodulate and decode said radio frequency signal in a header sensor at the other end of the line, the unique identifiers received are stored; and - a verification period that includes:

or compare in the header sensor the at least one unique identifier received with an internal list of unique identifiers (ID list).

Said internal list can be pre-configured during installation or alternatively it can be generated automatically by the sensor itself. header after initial startup.

In the event that all the unique identifiers of the installation (those present in the aforementioned list) have been received, the system goes back to the timing period. On the contrary, if one of the unique identifiers is not received during this period, the procedure further comprises generating a driver cut-off alarm state, preceeding its shipment according to a predetermined configuration as will be described below in the present invention.

According to a further preferred embodiment of the invention, in order to provide greater reliability to the system, a mechanism is also implemented that prevents the transmission of the driver's cut-off alarm the first time a sensor fault is detected, such as for example a fault counter or any other similar mechanism known to those skilled in the art.

An organization chart similar to that of Figure 1 is presented in Figure 2, which represents the method of protection of laying of electrical conductors according to the second aspect of the present invention. Said process is applied to the protection of electric conductor lines comprising a multitude of wires, such as for example the typical five-wire copper electrical conductors.

In fact, in certain installations (such as for example in public lighting installations) five-wire power lines are used (one wire for each of the three phases, one wire for the neutral and one grounding wire) ). The connections to the lampposts are made alternately between each of the phases and the neutral, so that the load in consumption of the different phases is balanced. On the other hand, the connection of the ground wire is carried out independently, and each specific number of lampposts must be reinforced by means of ground connections. On certain occasions, the subtraction of a single wire of this type of electrical conductors will not be easily detected by the procedure described above and shown in Figure 1, since there are multiple paths for the transmission of the radio frequency signal. Also, the cutting of the ground wire is not easy to detect because the signal is propagated through the above-mentioned pikes, even in the event that the ground wire is cut.

Therefore, to detect the cutting and subtraction of a single wire from a multi-wire electrical conductor, the procedure shown in Figure 2 The enclosed includes, in addition to the steps described with reference to Figure 1, the additional steps of:

- measure electrical parameters of the laying on the terminator sensor;

- measure the same electrical parameters of the laying in the header; Y

- compare, in the header, the electrical parameters measured in the terminator sensor with the electrical parameters measured in the header.

The measurement and comparison of the electrical parameters in the header of the laying can be carried out by the header sensor itself mentioned above, or by a multinode sensor that connects to each of the various lines in a complex wiring situation and that is directly connected to said header sensor.

Therefore, according to the method of the second aspect of the present invention, a cut-off alarm state of at least one wire is generated in case the electrical parameters measured in the terminator sensor and the electrical parameters measured in the header (sensor header or multinode sensor) do not match.

Also in this case, according to a further preferred embodiment of the invention, and in order to provide greater reliability to the system, a mechanism is also implemented that prevents the transmission of the cut-off alarm of at least one wire the first time a device is detected. failure of a sensor, such as a fault counter or any other similar mechanism known to those skilled in the art.

The preferred embodiment of the method and the device according to the second aspect of the present invention will be described in more detail below with reference to the attached figures. However, the person skilled in the art will easily understand that said description can be applied to the method and device of the first aspect of the present invention by simply eliminating the parts related to the measurement and comparison of electrical parameters at the ends of the laying.

The block diagram of Figure 3 shows the preferred embodiment of the method of the second aspect of the present invention. This figure shows a complex wiring comprising four electrical conductors (2). The method according to this embodiment of the present invention requires in this case the use of four terminator sensors (1) and a header sensor (3). It can be seen in Figure 3 that each terminator sensor (1) generates and injects a radio frequency modulated signal, which contains its own unique identifier (ID = 00001, 00002, 00003 and 00004, as an example) in the respective electrical conductor (2) . The characteristics of the radio frequency signal and the modulation and coding are chosen taking into account criteria of:

• Immunity against electrical noise and electromagnetic disturbances present in the line

· Good sensitivity in its detection / demodulation

• Compliance with existing regulations regarding signaling on low voltage lines

• Operation with or without connected low voltage network

The signal injected into the electrical conductor (2) is transmitted through it, and, eventually, reaches the header sensor (3). Said header sensor (3) is responsible for detecting, demodulating and decoding the received radio frequency signal, which contains, as mentioned above, the unique identifier of each terminator sensor (1). The interruption of the electrical conductor due to breakage or cutting (previous step to the subtraction), causes that the head sensor (3) does not receive the proper identifier of the corresponding terminator sensor (1), which is considered a condition of conductor cut-off alarm .

It can also be seen that each electrical conductor (2) comprises five wires (three wires for phases R, S and T, one wire for neutral N, and one grounding wire GND). In the terminator sensors (1), a series of electrical parameters (voltage, current, impedance, ...) are measured and transmitted together with the radio frequency signal, through the electrical conductors (2), to the Headboard. According to this preferred embodiment of the invention, a multinode sensor (4) is also included before the header sensor (3). Said multinode sensor (4) is responsible for adapting the connection and making the corresponding measurements of the electrical parameters in each of the electrical conductors (2).

As mentioned earlier, on certain occasions the breakage of only one of the wires of the electrical conductors (2) does not cause the interruption of the communication between the header sensor (3) and the corresponding terminator sensor (1). Therefore the header sensor (3), upon receiving the Radio frequency signal with the corresponding unique identifier will not detect a cut-off alarm status of the conductor from the terminator sensor (1). However, in this case, the breakage of a single wire causes the electrical balance between the different wires of the electric conductor (2) to be modified, which is detected as a variation of the electrical parameters measured at the different points of the line (specifically, measured in each terminator sensor (1) and in the header). In this way, the comparison between the electrical parameters measured at both ends of the electrical conductor (2) allows detecting a cut-off alarm state of at least one wire in that electrical conductor (2).

As explained above, the electrical conductor laying protection device according to the second aspect the present invention comprises:

- at least one terminator sensor (1) arranged to inject a radio frequency signal into at least one electrical conductor to be protected, modulated and encoded to transmit at least one unique identifier, as well as to measure electrical parameters and include them in said signal of radiofrequency;

- a header sensor (3) arranged to receive, demodulate and decode said radio frequency signal, as well as to measure the same electrical parameters and compare them with the electrical parameters transmitted from the terminator sensor (1); Y

In addition, the header sensor (3) is arranged to generate a driver cut-off alarm state in the absence of at least one unique identifier in the header.

Also, the header sensor (3) is arranged to generate a cut-off alarm state of at least one wire in the electrical conductor (2) in case the electrical parameters measured in the terminator sensor (1) and the electrical parameters measured in the header sensor (3) do not match.

According to another preferred embodiment of the present invention, the device further comprises a multinode sensor (4) connected to the header sensor (3). In this case, the electrical parameters in the header are measured in said sensor multinode (4) and transmitted to the header sensor (3).

Additionally, according to a preferred embodiment of the invention, the device further comprises a fault counter arranged to prevent the generation of a conductor cut-off alarm state and a cut-off alarm state of at least one wire the first time said wires are detected. alarm states

As seen in Figure 4, the header sensor (3) in turn comprises the following constituent elements.

First, the header sensor (3) includes at least one line interface (3A), which adapts the internal circuitry of the header sensor (3) to the characteristics of the electrical conductor line (2) to be protected . The basic functions of said at least one interface (3A) are:

• Filtering of the received signal (95-125 KHz according to EN 50065, band B)

· Adaptation of impedances between the internal circuitry and the impedance of the electric power distribution line

• Electrical insulation and safety

Secondly, the header sensor (3) includes a modem (3B) arranged to demodulate and decode the radio frequency signal transmitted by the electrical conductor (2). The modem (3B) can demodulate the signal transmitted in the work band, with good sensitivity and reliability, in order to avoid false alarms.

Third, the header sensor (3) includes a controller (3C) arranged to manage the header sensor (3) and generate and manage the alarms.

For its part, the alarm transmission module (3D) is arranged to transmit a signal as will be described hereinafter. Usually, said alarm transmission module (3D) is based on communications via GSM. However, those skilled in the art will readily understand that this feature is not limiting of the invention, since other communication systems known in the art can also be used.

The power supply unit (3E) is included in applications in which the device is applied to power lines that do not receive power supply during certain periods (for example, power lines). night public lighting). Said power block (3E) provides the necessary power to the different head sensor blocks (3), and implements a battery that is responsible for maintaining the security of the system during periods when there is no available power voltage.

Figure 5 shows the structure of the terminator sensor (1) according to the preferred embodiment of the invention. Said terminator sensor (1) comprises the following constituent elements.

• A line interface (1A) that adapts the internal circuitry of the terminator sensor to the characteristics of the line of electrical conductors to be protected.

• A modem (1 B) arranged in this case to modulate and encode the radio frequency signal with the identifier corresponding to said terminator sensor.

The signal is encoded and modulated in the D band described in the EN 50065 standard of CENELEC (95-125 KHz), for signaling in electric cables, in order to provide interoperability (not to interfere or be interfered with) with other services that could use the same electric conduction to transmit information.

• A controller (1C) of the terminator sensor that is responsible for providing the basic system timing, storing the functional parameters and managing communications through the modem (1 B).

Finally, as described above, the power supply unit (1 D) manages the charge of an internal battery to guarantee the operation of the terminator sensor (1) in the absence of power from the mains.

Referring now to Figure 6, the structure of the multinode sensor (4) according to the preferred embodiment of the invention is shown. Said multinode sensor (4) comprises a set of n line interfaces and n measuring elements (4A). The n line interfaces adapt the internal circuitry of the multinode sensor (4) to the characteristics of each of the n lines of electrical conductors (2) to be protected. On the other hand, the n measuring elements measure the electrical parameters of each of the n lines of electrical conductors (2) connected to it. The multinode sensor (4) also comprises a control and communications block (4B). Sensor controller Multinode (4) manages the general operation of the same to perform the measurements in each of the measurement blocks, while the communication element is responsible for transmitting the data corresponding to said measurements to the header sensor (3) to allow its processing and comparison with the measurements of electrical parameters from the terminator sensors (1).

Finally, as in the previous cases, the power supply unit (4C) manages the charge of an internal battery to guarantee the operation of the multinode sensor (4) in the absence of power coming from the mains.

The method and device of the present invention can operate according to a centralized model or according to a direct model, respectively represented in Figures 7 and 8.

As shown in the attached figure 7, according to the centralized model, in the absence of at least one unique identifier in the header sensor (3) (in this case the one coming from the terminator sensor (16)), or in case If the electrical parameters measured in the terminator sensor (12, 14, 16) do not correspond to the electrical parameters measured in the header sensor (3), an alarm (5) is generated (for example through a GSM / GPRS), and is sent to a database (6) of an alarm center that in turn is responsible for sending the alarm information (5) to at least one programmed final recipient (for example, to a user mobile (7) or mobile security center (8) by SMS message, or via the Internet to a user computer (9)). This centralized model of the process of the present invention provides the following advantages:

· The information is centralized and communications protocols are more secure (bidirectional protocol, alarm confirmation, ...)

• The status of the installation can be verified remotely (via a web interface) at any time

• The service provider also provides support and maintenance services to users

On the other hand, according to the direct model shown in Figure 8, in the absence of at least one unique identifier in the header sensor (3) (in this case also the one coming from the terminator sensor (16)), or in case that the electrical parameters measured in the terminator sensor (12, 14, 16) do not correspond to the electrical parameters measured in the header sensor (3), an alarm (5) is generated (for example through a GSM / GPRS connection), and sent directly to a programmed end user (for example, a user's mobile (7) or a central mobile of security (8)) by, for example, an SMS message.

In this case the structure is even simpler, the simplicity of the procedure being its advantage.

Although the present invention has been described according to various specific embodiments thereof, these should not be construed as limiting the invention and those skilled in the art can easily apply modifications to the described embodiments without thereby departing from the scope of the invention. For example, it will be apparent that the method and device of the present invention can be applied to both copper lines and any other electrical conductor that wishes to protect itself.

In addition, as is easily understood from the above description, preferred embodiments thereof will allow its application both with applied voltage and in the event that the line has been temporarily disconnected from the general power grid.

Claims

1. Procedure for protection of laying of electrical conductors, characterized in that it comprises sequentially:

- a timing period comprising:

or injecting at one end of the electric conductor (2) by means of a terminating sensor (1, 12, 14, 16) a radiofrequency signal, modulated and encoded to transmit at least one unique identifier;

or transmitting said radiofrequency signal by said electrical conductor (2);

or receiving, demodulating and decoding said radio frequency signal in a header sensor (3) at the other end of the line; Y

- a verification period comprising:

or compare in the header sensor (3) the at least one unique identifier received with an internal list of unique identifiers;

The procedure also includes:

- generate a driver cut-off alarm status in the absence of at least one unique identifier in the header sensor (3).

2. Method according to claim 1, characterized in that the electrical conductor (2) comprises a multitude of wires, and the method further comprises the steps of:

- measure electrical parameters of the laying on the terminator sensor (1, 12, 14, 16);

- including said electrical parameters measured in the radio frequency signal transmitted by said electrical conductor (2);

- measure the same electrical parameters of the laying in the header;

- compare, in the header, the electrical parameters measured in the terminator sensor (1, 12, 14, 16) with the electrical parameters measured in the header; Y

- generate a cut-off alarm state of at least one wire in case the electrical parameters measured in the terminator sensor (1, 12, 14, 16) and the electrical parameters measured in the header do not match.

3. Method according to claim 2, characterized in that the electrical parameters in the header of the laying are measured by a multinode sensor (4) connected to the header sensor (3).

4. Method according to any of claims 2 and 3, characterized in that the electrical parameters measured in the terminator sensor (1, 12, 14, 16) and in the header of the line are selected from the group consisting of voltage, current, impedance and any combination thereof.

5. Method according to any of claims 2 to 4, characterized in that the electric conductor (2) comprises five wires.

Method according to any of the preceding claims, characterized in that the electrical conductors (2) are made of copper.

Method according to any one of the preceding claims, characterized in that it further comprises preventing the generation of an alarm state the first time a conductor cut-off alarm state or a cut-off alarm state of at least one conductor wire is detected. .

Method according to any of the preceding claims, characterized in that, in case of generating an alarm state, it also comprises:

- send an alarm signal to a database (6) of an alarm center; Y

- send alarm information from said alarm center to at least one programmed final recipient (7, 8).

9. Method according to any of the preceding claims, characterized in that, in case of generating an alarm state, it further comprises:

- send an alarm signal directly to a programmed end user

(7, 8) through an SMS message.

10. Method according to any of claims 8 and 9, characterized in that the alarm signal is generated by a GSM / GPRS connection.

11. Method according to any of the preceding claims, characterized in that it further comprises programming the header sensor

(3) to receive several unique identifiers, each of said unique identifiers corresponding to a different electrical conductor section (2).

12. Method according to any of the preceding claims, characterized in that it further comprises:

- pre-program during the installation the internal list of unique identifiers

Method according to any one of claims 1 to 11, characterized in that it further comprises:

- Automatically generate, by the header sensor itself (3), the internal list of unique identifiers after initial startup.

Method according to any of the preceding claims, characterized in that it is applicable both with voltage applied to the electrical conductors (2) and without voltage applied to them.

Protection device for laying electrical conduits, characterized in that it comprises:

- at least one terminator sensor (1, 12, 14, 16) arranged to inject a radio frequency signal into at least one electrical conductor (2) to be protected, modulated and coded to transmit at least one unique identifier;

- a header sensor (3) arranged to receive, demodulate and decode said radio frequency signal; Y

- an internal list of unique identifiers with which to compare the at least one unique identifier transmitted in said radio frequency signal;

the header sensor (3) is also arranged to generate a driver cut-off alarm state in the absence of at least one unique identifier in the header sensor (3).

Device according to claim 15, characterized in that the electrical conductor (2) comprises a multitude of wires, and that the terminating sensor (1, 12, 14, 16) is further arranged to measure electrical parameters and include them in the radio frequency signal transmitted by said electrical conductor (2), the header sensor (3) being arranged to measure the same electrical parameters and compare them with the electrical parameters transmitted from the terminator sensor (1, 12, 14, 16); the header sensor (3) being further arranged to generate a cut-off alarm state of at least one wire in case the electrical parameters measured in the terminator sensor (1, 12, 14, 16) and the electrical parameters measured in The header does not match.

Device according to claim 16, characterized in that it further comprises a multinode sensor (4) connected to the header sensor (3) arranged to measure the electrical parameters in the header and transmit them to the header sensor (3).

18. Device according to any of claims 16 and 17, characterized in that the electric conductor (2) comprises five wires.

19. Device according to any of claims 15 to 18, characterized in that the electrical conductor (2) is made of copper.

20. Device according to any one of claims 15 to 19, characterized in that it further comprises a fault counter arranged to prevent the generation of an alarm state the first time a conductor cut-off alarm state or an alarm status is detected. cut at least one conductor wire.

21. Device according to any of claims 15 to 20, characterized in that said head sensor (3) comprises:

- at least one line interface (3A) that adapts the internal circuitry of the header sensor (3) to the characteristics of the line of electrical conductors (2) to be protected;

- a modem (3B) arranged to demodulate and decode the radio frequency signal;

- a controller (3C) arranged to manage the header sensor (3) and generate and manage the alarms; Y

- an alarm transmission module (3D) arranged to transmit an alarm signal.

22. Device according to claim 21, characterized in that the alarm transmission module is based on communications via GSM.

23. Device according to any of claims 15 to 22, characterized in that said at least one terminator sensor (1, 12, 14, 16) comprises:

- a line interface (1A) that adapts the internal circuitry of the terminator sensor (1, 12, 14, 16) to the characteristics of the line of electrical conductors (2) to be protected;

- a modem (1 B) arranged to modulate and encode the radio frequency signal; Y

- a controller (1C) of the terminator sensor (1, 12, 14, 16).

24. Device according to any of claims 17 to 23, characterized in that said multinode sensor (4) comprises:

- a set of multiple line interfaces that adapts the circuitry internal of the multinode sensor (4) to the characteristics of each line of electrical conductors (2) to be protected;

- a set of measuring elements to measure the electrical parameters of each line of electrical conductors (2) to be protected;

- a multinode sensor controller (4); Y

- a communication element with the header sensor (3).

Device according to any of claims 15 to 24, characterized in that the header sensor (3), the multinode sensor (4) and the at least one terminator sensor (1, 12, 14, 16) each further comprise a power supply block. (1 D, 3E, 4C) to provide power during periods without voltage applied to electrical conductors (2).