WO2003034079A1

WO2003034079A1 - Signal transfer cable and the surveillance system therefor

Info

Publication number: WO2003034079A1
Application number: PCT/FR2002/003332
Authority: WO
Inventors: Patrick Jamet; Thierry Linossier
Original assignee: Sagem Sa
Priority date: 2001-10-17
Filing date: 2002-09-30
Publication date: 2003-04-24
Also published as: FR2830941A1; FR2830941B1

Abstract

The invention relates to a signal transfer cable and the surveillance system therefor. In order to monitor a cable (1), several surveillance devices (4) are distributed along the length of the cable (1). The aforementioned devices capture data (D) that are intrinsic or extrinsic to the cable for the wireless transmission thereof to a reader (5). Said devices can be powered by (i) the alternating current (IA) in an inductively-coupled conductive element which is included in the cable, or (ii) a non-modulated carrier transmitted by the reader possibly via a radiating cable.

Description

Signal transport cable and its monitoring system

The present invention relates to the monitoring of data intrinsic to a signal transport cable, such as an electric power cable, or a telecommunications cable, including a fiber optic cable.

It is particularly aimed at recording characteristic thermal and / or mechanical data at one or more predetermined locations on the cable. It does not concern the monitoring of electrical characteristics such as voltage and current in an electrical cable.

To this end, a signal transport cable comprising several monitoring devices distributed along the cable, is characterized in that each monitoring device is miniaturized on a substrate and integrated in the cable, and comprises means for picking up at least one data intrinsic to the cable, a means for radio-transmitting the data received together with a respective identifier of the monitoring device, and supply means for supplying DC voltage to the means for picking up and the means for transmitting.

According to certain embodiments of the invention described in more detail below, the supply means in the monitoring devices can be coupled by electromagnetic induction to at least one conductive element included in the cable and capable of being traversed by a current AC, or receive a radio carrier of unmodulated power emitted from outside the cable. The monitoring devices in the cable in the form of miniature substrates are integrated into the cable during the manufacture of the latter according to one of the following embodiments. According to a first embodiment, the monitoring devices are incorporated in the cable sheath. According to a second embodiment, the monitoring devices are fixed to the internal periphery of the cable sheath, for example on a strip of insulating material added longitudinally under the cable sheath. The tape may include two longitudinal electrical conductors connected to the supply means in the monitoring devices and having ends capable of being connected to a source of direct voltage.

The invention also relates to a system for monitoring the signal transport cable according to the invention. The system comprises several miniature monitoring devices distributed along the cable and integrated in the cable, as defined above, and a reading means external to the cable for receiving the data transmitted by the monitoring devices. The reading means can be portable. The reading means may comprise a radiating cable along the cable and a receiver connected to one end of the radiating cable to receive the data transmitted by the means for transmitting in the monitoring devices. For a cable, the monitoring devices of which receive power supply from an unmodulated carrier, the reading means can itself transmit the unmodulated carrier to the monitoring devices. In this case, the reading means may comprise a radiating cable running along the cable to be monitored, a means for generating the unmodulated power carrier through the radiating cable to the supply means in the monitoring devices, and a receiver for receiving through the radiating cable the data transmitted by the means for transmitting in monitoring devices.

Other characteristics and advantages of the present invention will appear more clearly on reading the following description of several preferred embodiments of the invention with reference to the corresponding appended drawings in which: FIG. 1 is a schematic longitudinal view of a cable to three conductors incorporating monitoring devices in a monitoring system according to a first embodiment of the invention;

- Figure 1A is a cross section taken along line A-A of the cable of Figure 1; Figure 2 details a monitoring device according to the first embodiment of the invention coupled by electromagnetic induction to a conductive element of the cable and transmitting an identifier and data to a radio reader-receiver;

- Figure 3 schematically shows a monitoring system according to a second embodiment of the invention, in which the monitoring devices are remotely powered by a radio carrier transmitted by the reader;

- Figure 4 schematically shows a monitoring system according to a third embodiment of the invention, in which the devices monitoring are supplied through electrical conductors attached to the cable to be monitored;

- Figure 5 schematically shows a monitoring system according to a fourth embodiment of the invention, in which the monitoring devices are remotely powered by electromagnetic induction as in the first embodiment, but transmit identifiers and data to a reader through a radiating cable; and FIG. 6 schematically shows a monitoring system according to a fifth embodiment of the invention, in which the monitoring devices are remotely supplied via a radiating cable which receives identifiers and data transmitted by the monitoring devices.

According to a first embodiment of the invention shown in FIGS. 1 and 2, a surveillance system monitors a signal transport cable 1 such as an electric power cable or a telecommunications cable comprising several insulated metallic wire conductors 2 contained in an outer sheath or envelope 3. The monitoring system comprises several passive monitoring devices 4 distributed longitudinally in the cable and integrated in the cable, that is to say incorporated in the sheath 3 or fixed under the sheath 3 during the cable manufacturing. According to the embodiment illustrated in FIGS. 1 and 1A, the devices 4 are embedded in the sheath 3. The monitoring system also includes a mobile and portable radio reader-receiver 5, external to the cable and powered by battery or by the electrical sector.

Each monitoring device 4 shown in detail in FIG. 2 is organized around a microcontroller 6 including a non-volatile memory having previously memorized in particular a respective identifier ID of the monitoring device. In the device 4 are connected to the microcontroller 6 at least one sensor 7 for picking up data D relating to the cable 1, a radiofrequency transmitter _^ . 8 for periodically transmitting the identifier ID and the data D to the radio reader-receiver 5 external to the cable, and a supply circuit 9 for supplying the aforementioned elements 6, 7 and 8. All the elements 6 to 9 are miniaturized and integrated on a miniature dielectric substrate of a few square millimeters to a few square centimeters. In particular, the radio transmitter 8 and the power supply circuit 9 respectively comprise an antenna 81 of the plate or patch antenna type (in English terminology "patch") and a coupling inductor 91 printed in the substrate.

The data D captured by the sensor 7 and applied in the form of a binary word to the microcontroller 6 may be a thermal or mechanical characteristic prevailing in the cable, such as the temperature or the pressure or the hygrometric state prevailing in the cable, or else a elongation, measured inside the cable where the sensor 7 is located. As a variant, several of these data intrinsic to the cable are picked up by several sensors included in the device 4 and emitted by the transmitter 8.

The identifier ID issued jointly with the data item D serves to distinguish the monitoring device 4 relative to the other monitoring devices and implicitly to locate the monitoring device along the cable.

The identifier ID and the captured data D are sent periodically, for example by modulation amplitude, frequency or phase in the microcontroller 6 and by frequency transposition in the transmitter 8 which transmits a modulated carrier of frequency F. The emission is cyclic as long as the supply circuit 9 supplies the elements 6, 7 and 8 so that the data and identifiers transmitted by the neighboring monitoring devices of a given monitoring device do not overlap and are thus time multiplexed. The transmission frequency F of the transmitter 8 is different from the signal frequencies normally transmitted by the conductors 2 of the cable 1. If the cable transmits an electrical energy signal, the baseband frequency of the signal modulated in the microcontroller 6 is different from the frequency of the alternating voltage of 50 or 60 Hz, and if the cable transmits a telecommunications signal, the emission frequency F does not belong to the range of useful frequencies of the telecommunications signals transmitted by the cable . For example, the transmission frequency F is equal to 433 MHz.

According to the first embodiment shown in Figures 1 and 2, the supply circuit 9 is inductively coupled with a supply conductive element included in the cable and capable of being traversed by an electric current IA after the cable is installed. The conductive element consists of one or more of the wire conductors

2 in the cable, or else consists of any other metal element extending longitudinally, including helically, in the cable, such as a screen or shielding 31 incorporated in the sheath 3 of the cable, or such that a wire or strand of wire 32 in the center of the cable or one or more wire frames 33 embedded in the sheath 3 and / or housed under the sheath 3 inside the cable.

In order not to disturb the signals transmitted by the cable, the frequency FA of the remote supply current injected into the conductive supply element _. , included in the cable does not fall within the useful frequency range of the signals transmitted in the cable. However, the frequency FA must not be too high so that the remote supply current does not weaken too much. Typically for a range of a few hundred meters, the alternating supply current is a few milliamps and has a frequency FA of less than about 1 MHz. For an electric power cable, the supply frequency FA can be between 1 kHz and 1 MHz. For a low speed telecommunications cable, the frequency FA can be between 100 kHz and 1 MHz. The IA remote power supply is produced by a current generator 10 connected to one end of the supply conductor element 2, 31, 32, 33. The supply circuit 9 of the monitoring device 4 is coupled by electromagnetic induction to the supplying conductive element by means of the inductor 91 which, with a capacitor 92, constitutes an oscillating circuit tuned to the frequency FA of the remote supply current IA. The induced alternating voltage VA at the terminal of the oscillating circuit is applied to means 93 to generate a direct voltage Vd supplying the microcircuits 6, 7 and 8 included in the device 4. The means 93 can comprise a rectifier, a filter and a limiter voltage to supply the DC voltage Vd as well as a demodulator for supplying a clock signal H to a time base included in the microcontroller 6.

According to a variant of the first embodiment as well as according to other embodiments described below, the cable to be monitored is a cable transporting at least an optical signal and containing optical fibers in place of the wired conductors 2 or in combination with them this. The cable furthermore comprises at least one element conducting the remote supply current IA at the frequency FA in order to induce by inductive coupling the induced voltage VA which is converted into direct supply voltage Vd. The conducting element can also be a metal reinforcement such as a strand or a metallic wire in the center of the cable and / or one or more reinforcements at the periphery of the cable or under the external sheath of the cable.

According to a second embodiment shown in Figure 3, the monitoring system monitors a cable la of the same type as the cable 1 according to the first embodiment, but without requiring a supply current conducting element. For example, the cable to be monitored can be a fiber optic cable without a metallic element.

In this second embodiment, the portable reader 5a transmits an unmodulated carrier PA, acting as a power supply signal, which is picked up by a receiving antenna in the form of a microwave antenna of the pellet type integrated in each monitoring device 4a incorporated in the cable la in order to apply it to a supply circuit 93a supplying a supply voltage Vd and a clock signal H. The antenna reception above with an impedance matching circuit can be confused with the transmitting antenna 81a.

As a variant, the receiving microwave antenna can be replaced by a resonant circuit 91a-92a tuned to the frequency of the power carrier PA transmitted by the reader 5a.

Thus each monitoring device 4a is still purely passive but is supplied by a power source external to the cable of the invention to be monitored. Furthermore, the device 4a contains microcircuits 6a, 7a and 8a similar to those 6, 7 and 8 described in the first embodiment, so that these circuits transmit the identifier ID and at least one datum D modulating the frequency carrier F to reader 5a. In practice, the portable reader 5a is sensitive to the reception of the identifier ID and of the data D in response to the unmodulated power supply carrier PA acting as a read request signal which it transmits, for a distance of l order of the meter with respect to each monitoring device 4a.

According to a third embodiment shown in Figure 4, the monitoring system monitors a cable lb which does not necessarily include an electrically conductive element.

In this third embodiment, the monitoring devices 4b have their miniature substrates fixed beforehand, for example by gluing, on one face of a thin strip 41 of flexible and insulating material. The ribbon 41 supporting the monitoring devices 4b is integrated under the sheath 3 of the cable lb during the manufacture of the cable. According to a first variant, the tape 41 supports two metallic conductors printed or longitudinal glued 42, for example made of copper or aluminum. Ends of the conductors 42 are connected to the terminals of a DC voltage source 10b such as batteries. Supply terminals of the elements 6b, 7b and 8b in each monitoring device 4b are connected to the supply conductors 42 extending on or under the substrate of the device 4b, directly or via a DC converter -continuous included in the supply circuit 9b. The devices 4b are thus supplied in parallel by the DC voltage source 10b. The identifier ID and the data D are sent to the reader-receiver 5b in the same way as in the previous embodiments.

According to a second variant, the strip 41 does not include conductors 42 and each monitoring device 4b comprises a supply circuit for example such as that 9a according to FIG. 3, or 9c or 9d according to FIG. 5 or 6.

According to a fourth embodiment shown in Figure 5, the electrical or telecommunications cable of the invention to be monitored is of the same type as the cable 1 according to the first embodiment (Figure 2) or lb according to the third embodiment (Figure 4). For example, the cable le includes a conductive element capable of being traversed by an alternating current of remote power supply IA at the frequency FA and coupled by electromagnetic induction to the inductor 91c included in the supply circuit 9c of each monitoring device 4c . In the fourth embodiment, the monitoring system comprises, as reading means, a radiating cable 51c and a reader-receiver 5c. The radiating cable 51c is for example of the coaxial type with periodic patterns of slots or holes and extends along the cable to be monitored and against it or at a distance therefrom up to about 1 meter. The reader 5c is coupled to one end of the radiating cable 51c to receive the identifiers ID and the data D modulating the frequency carrier F and transmitted cyclically by the devices 4c, each in turn. In practice, the radiating cable 51c is installed in the same underground pipe containing the cable or is fixed against the cable before the installation thereof.

A fifth embodiment according to the invention combines remote supply by unmodulated power carrier PA according to the second embodiment (FIG. 3) and reception of identifier and data by radiating cable 51d according to the fourth embodiment (FIG. 5), as shown in FIG. 6. The cable of the invention to be monitored ld may not include a conductive element since ¹ no remote power supply current passing through the cable ld is necessary. Each monitoring device 4d on or incorporated in the cable to be monitored ld is analogous to the monitoring device 4a according to the second embodiment shown in FIG. 3.

The reading means according to the fifth embodiment consists of a radiating cable 51d along the cable to be monitored ld and a reader 5d. 5d player not only has a receiver but also of an unmodulated PA power carrier transmitter emitted through the radiating cable 51d and broadcast by the latter to the monitoring devices 4d. The antennas or the tuned circuits 91d-92d in the supply circuits 9d pick up the carrier PA and transform it into a direct voltage Vd applied to the microcircuits 6d, 7d and 8d included in the devices 4d. As in the fourth embodiment, the radio transmitter 8d in each monitoring device 4d transmits cyclically in a predetermined time window the identifier ID and the respective data D modulating the carrier at the frequency F which is picked up by the radiating cable 51d so that reader 5d retrieves identifiers and data.

Claims

1 - Cable, signal transport comprising several monitoring devices (4) distributed along the cable (1), characterized in that each monitoring device is miniaturized on a substrate and integrated in the cable (1), and comprises a means (7) for picking up at least one piece of data (D) intrinsic to the cable, means (8) for radio-transmitting the data collected together with a respective identifier (ID) of the monitoring device (4), and supply means (9) for supplying direct voltage (Vd) to the means for picking up and the means for transmitting.

2 - Cable according to claim 1, characterized in that the supply means (9; 9c) in the monitoring devices (4; 4c) are coupled by electromagnetic induction to at least one conductive element (2, 31, 32 , 33) included in the cable (1; le) and likely to be crossed by an alternating current (IA).

3 - Cable according to claim 2, wherein the current (IA) capable of passing through the conductive element (2, 31, 32, 33) has a frequency (FA) not belonging to the useful frequency range of an electrical or telecommunications signal transmitted over the cable.

4 - Cable according to claim 2 or 3, wherein the current (IA) capable of passing through the conductive element (2, 31, 32, 33) is a few tens of milliamps and has a frequency less than about 1 MHz. 5 - Cable according to claim 1, characterized in that the supply means (9a; 9d) in the monitoring devices (4a; 4d) receive an unmodulated power carrier (PA) emitted from outside the cable .

6 - Cable according to any one of claims 1 to 5, wherein the monitoring devices (4) are incorporated in the sheath (3) of the cable.

7 - Cable according to any one of claims 1 to 6, characterized in that the monitoring devices (4b) are fixed under the sheath (3) of the cable.

8 - Cable according to claim 7, characterized in that the monitoring devices (4b) are fixed on a tape (41) of insulating material reported longitudinally under the sheath (3) of the cable (lb).

9 - Cable according to claim 7, characterized in that the monitoring devices

(4b) are fixed on a tape (41) of insulating material which is attached longitudinally under the sheath (3) of the cable (lb) and which comprises two longitudinal electrical conductors (42) connected to the supply means (9b) in the monitoring devices (4b) and having ends capable of being connected to a DC voltage source (10b). 10 - System for monitoring a signal transport cable comprising several monitoring devices (4) distributed along the cable (1), characterized in that each monitoring device (4) is miniaturized on a substrate and integrated in the cable ( 1), and comprises a means (7) for picking up at least one datum (D) intrinsic to the cable, a means (8) for radio-transmitting the sensed datum together with a respective identifier (ID) of the monitoring device (4), and supply means (9) for supplying direct voltage (Vd) to the means for picking up and the means for transmitting, and the system further comprises reading means (5) external to the cable for receiving the data transmitted by the monitoring devices.

11 - System according to claim 10, wherein the reading means (5) is portable.

12 - System according to claim 10 or 11, wherein the reading means (5a; 51d, 5d) transmits the unmodulated power carrier to the monitoring devices.

13 - System according to claim 10, characterized in that the reading means comprises a radiating cable (51c) along the cable to be monitored (the) and a receiver (5c) connected to one end of the radiating cable to receive the data (D) transmitted by the means for transmitting (8c) in the monitoring devices (4c).

14 - System according to claim 10, characterized in that the supply means (9a; 9d) in the monitoring devices (4a; 4d) receive an unmodulated power carrier (PA) emitted from outside the cable, and the reading means comprises a radiating cable (51d) along the cable to be monitored (ld), means (5d) for generating a power carrier unmodulated (PA) through the radiating cable to the supply means

(9d) in the monitoring devices (4d), and a receiver (5d) for receiving through the radiating cable the data (D) transmitted by the means for transmitting (8d) in the monitoring devices

(4d).