FR2485745A1 - Subscriber telephone wire fault locating appts. - has switchable low, medium and high voltage supply to fuse wires and measures line resistance to fault - Google Patents

Abstract

The device locates a fault in a twin-wire telephone line where the two wiresare separated by insulation. The device has a low power generator which applies a high voltage to the device output connected to the line to generate an arc between the wires at the fault. As the arc destroys the insulation and the line impedance drops the device switches in a mid-voltage medium power voltage generator to increase the effect and then finally a low voltage high power generator to weld the wires together. The voltages are typically 1400-2000 V, 600-800 V and 24 V, the last being provided by accumulators. Once the above stages are completed the line resistance is measured to determine the length of line from the device connection point to the fault.

Description

 The invention relates to a method and an apparatus for locating faults on an electric line comprising at least two conductors separated by an insulating material.

 A typical example of application of the invention is the subscriber telephone line, usually composed of two parallel conductors, copper-based, isolated by an insulating material, such as neoprene. As such a line is generally suspended from wooden poles, the cases of deterioration, by wear or by accident, are relatively numerous. The deterioration can be frank, corresponding to a cut of at least one of the conductors or to their short-circuiting, but it is more often imperfect, for example in the event of local wear.

To the mechanical cause of incomplete deterioration are added the effects of humidity which, by penetrating between the conductors and the oxidizers, reduce the insulation resistance. This results in a progressive alteration in the quality of transmission, which is unpleasant for the subscriber and finally, the disruption of the line.

 To repair, it is made beforehand, using conventional techniques, a determination of the distance separating the defect from a given point of the line, which will be designated "line entry", generally the subscriber. One of these techniques, called ultrasound, uses the echo of an electric wave on the fault to indicate the distance on an echometer placed at the entrance of the line. Another technique is to apply at the entrance to line two. low frequency signals (1000 Hz for example), square and symmetrical with respect to the earth, respectively on the two conductors, and to determine the location of the fault by moving along the line to detect a variation in the signal In reality, all the conventional techniques for determining the distance of the defect prove to be effective only when the defect is clear.

 However, it is desirable, and sometimes necessary, to repair the line before the imperfect deterioration becomes a clear defect. The principle is to locate the defect by making an imperfect deterioration a frank defect. A known method is to apply a high voltage, of the order of 1.2 kV, of fixed energy high enough to form a weld.

two conductors at the fault location. The disadvantage of this process is that the application of high voltage with this energy sometimes causes the insulation to ignite instead of the fault, thus propagating the fault on the line and also risking creating a fire depending on the surrounding environment. .

 The invention remedies the drawbacks of the prior art for locating faults.

 A method according to the invention for locating an insulation fault on an electric line comprising at least.

two conductors separated by an insulator is of the type comprising the application of a high voltage to the line and is characterized in that said high voltage is intended to initiate an electric arc between the conductors and has for this purpose a low intensity, and in that it consists, after the initiation of said electric arc, in reducing the voltage while increasing the intensity of the current as a function of the electrical resistance of the line so as to melt said insulator at the location of the fault, then solder the conductors together or destroy at least one of them at the fault location.

 Consequently, the application of low intensity high voltage avoids the ignition of the insulation but only causes the initiation of an electric arc, the ignition being then avoided by decreasing the voltage as and when the current must pink to melt the insulator and ultimately produce the clear fault.

 Although the decrease in voltage and the concomitant increase in current can be done continuously depending on the resistance of the line, the implementation of the process turns out to be easier and as efficient as acting in stages, ie by applying a medium voltage of medium intensity to melt the insulation and a low voltage of high intensity for welding or cutting the line at the location of the fault.

 As a corollary, an apparatus according to the invention for implementing the method is characterized in that it comprises means generating variable voltage and current and control means reacting to the electrical resistance of the line to make glassware simultaneously said voltage from a maximum value to a minimum value and said current from a minimum current to a maximum current.

 Advantageously, said variable voltage and current generating means will comprise a high voltage & low current generator, a medium voltage medium current generator and a low voltage high current generator, and the control means will comprise a switching device activating successively said high, medium and low voltage generators.

 The characteristics and advantages of the invention will emerge more clearly from the description which follows, given with reference to the accompanying drawings.

In the drawings
- Figure 1 schematically illustrates an example of reality
sation of a compliant fault location device;
to the invention
- Figure 2 is a graph illustrating the localization process
fault location according to the invention implemented by
the device shown in Figure 1, the graphs defined
health in time (t of the abscissa axis) the evolution
process phases and voltages U (axis of ordinates-
born) involved in each phase; and
- Figure 3 illustrates in detail an embodiment
of the device shown in Figure 1.

 Although the invention applies to any power line comprising at least two conductors separated by an insulating material, the following description will be made with reference to a telephone line 10 (see Figures 1 and 3 composed of two parallel conductors 10a, 10b , separated by an insulator 11 and having an input 12 (figure 1) with two terminals 12a, 12b (figure 3).

 It is assumed that an imperfect fault is located at a location 13 on the line, separated from the input 12 by a distance d.

 For the location of the fault 13, there is arranged (FIGS. 1 and 3) a device 20 according to the invention, the output 21 (constituted by the terminals 21a and 21b of FIG. 3) is connected to the input 12 ( terminals 12a, 12b) of line 10.

The apparatus 20 schematically represented in FIG. 1 essentially comprises a high voltage generator with
low intensity 22, a medium voltage generator with medium intensity 23 and a low voltage generator with high intensity 24, and a control device 25. The control device 25 connects in parallel the three generators 22, 23, 24 to the output 21 of the device 20, symbolically by means of three respective switches 22a, 23a, 24a constituted by the relay blades with control members 22b, 23b ', 24b. The control device 25 comprises a control element 26 having an input connected to the output 21 of the device and outputs respectively connected to the relay control members 22b, 23b, 24b.

 In practice, the device 20 will include an ohmmeter 27 enabling the operator to control the state of the line.

This ohmmeter is connected to the output 21 of the device 20 by means of a switch 27a constituted by a relay with a control member 27b connected to an output of the control element 26, and normally injects continuously into the line 10 a constant direct current to indicate, in a conventional manner, the value of the electrical resistance of the line. In addition, the apparatus 20 will generally be associated with a device 28 for determining the distance d of the defect which has become clear 13 'relative to the input 12 of the line. The device 28, of the conventional type, is also symbolically connected to the output 21 of the device 20, by means of a switch 28a constituted by a relay with control member 28b connected to an output of the element of command 26.

The fault location method according to the invention, which is executed by the apparatus 20 of Figure 1, will be understood with reference to the graph of Figure 2. The initial state is assumed to be that where the switches are all open , as shown. At the beginning, we close the switch 27e to know, on reading the ohmmeter, re, the initial resistance Ro of the line and, consequently, the importance of the fault. By pure convention, we will consider that a line is faulty and repairable for imperfect fault corresponding to an initial resistance of less than 250 KR. At the start of the process according to the invention, the switch 22e is closed to apply a low voltage Uo of low intensity, intended to strike an electric arc between the conductors 10a, 10b of the line 10 at the location of the fault 13.A striking the arc, the resistance of the line decreasing, and taking into account the internal resistance of the generator 22, a drop in voltage at the output 21 of the apparatus 20, representative of the drop in resistance of the line , will be detected and, beyond a predetermined voltage threshold U44, the control element 26 reacts to open the switch a and close the switch 23e. The line then receives a medium voltage
U20 of medium intensity, intended to melt the insulator 11 at the level of fault 13 without ignition of the insulator. This process phase is called "burning phase". As the insulator melts, the mechanical tension existing between the conductors 10a and 10b will attract them to one another and will consequently reduce the resistance of the; line. As previously, this reduction in the resistance of the line will correspond to a reduction in the voltage U20 and, beyond a predetermined voltage threshold U, the control element 26 reacts to open the switch 23a and close the switch 24a. A low current Us0 of high intensity is then applied to the line, intended to weld the two conductors lOa, lOb between them at location 13. This phase is therefore called "welding phase" .When welding takes place, the resistance of the line decreases considerably and, as a result, the value of U30 falls.

After a fall to a value U31 detected by the control element 26, the latter opens the switch 24a. The conventional phase of determining the distance d can then be carried out efficiently with great precision, by closing the switch 28a.

The values of the voltages involved are determined in practice according to the nature of the line and given conditions. Thus, possibly, with the assembly of FIG. 1, the high voltage U1O can be adjusted as a function of the value of R9, the medium voltage as a function of the nature of the insulator, of the spacing of the conductors, etc. However, it should be noted that in the absence of an adjustment, the control element will automatically adjust the durations of the phases accordingly.
Until the formation of the clear defect. Likewise, the welding phase can be transformed into a break, if, following the bringing together of the conductors, at least one of them breaks. This break will be detected by the control element 26, which may govern Consequently, and in any case by the ohmmeter 27 Furthermore, the limit values of the voltages UX1, U and U31 will be determined in particular as a function of the internal resistance of the generators and of the results of experience. For example, Udo can vary from 1,400 to 2,000 V, U from 600 to 800 V, and U30 can be a nominal voltage of 24 V, all these voltages being continuous. However, it is clear that the invention can be applied to alternating voltages. For the voltage values indicated above, the following intensities were observed. During the ignition phase, the average intensity value is of the order of 10 mA, an intensity exceeding 100 mA causing the phase to change; during the burning phase, the average value is of the order of 100 mA, an intensity greater than 300 mA causing the phase to change; and during the welding phase, an intensity of 4A completes the process of the invention.

 From this description it appears that the process of the invention can be easily generalized by replacing the generators 22, 23 and 24 by a generator of variable voltage and intensity, these being continuously adjusted by a control device reacting to variations resistance of the line until the frank fault is obtained.

 FIG. 3 shows an example of a concrete embodiment of the device 20 represented in FIG. 1. The essential components of the device 20 are referenced therein by the same numbers, namely the generators 22, 23 and 24 and the control device 25. As in Figure 1, the control device includes the control element 26 and the relay (24e, 24b). The relay (2Zá, 22b) differs from the relay (22a, 22b) of Figure 1 by its operation, the latter remaining closed during the two phases of ignition and burning due to the common structure of the generators 22, 23 delta figure 3. The relay (23'a, 23'b) operates in reverse of the relay (23a, 23b). The ohmmeter 27 and the device 28 have been omitted in FIG. 3.

 More specifically, the low voltage generator 24 is a storage battery. The generators 22, 23 firstly comprise an oscillator (at 7 kHz, for example) formed by an amplifier 30, the output of which is looped back by a resistor 31 at its input, the latter being connected to earth by a capacitor 32. The output of the oscillator drives a JK flip-flop, 33, dividing the signals by two and delivering to its two outputs Q, Q symmetrical signals in phase opposition. The output of the oscillator further controls a monostable flip-flop 34 delivering pulses adjustable duration by means of variable resistance 34a. The signals leaving Q and Q are respectively modulated as a function of the pulses leaving the monostable flip-flop 34 by two NAND gates 35, 36, whose respective outputs drive amplifiers 37, 38 with adjustable gain, adjusted by the control element 26 via the connection 39. The outputs of amplifiers 37 and 38 are connected to the primary 40a of a transformer 40 (a power toroid for example) at secondary 40b. The primary coil 40e has its midpoint connected to an operating voltage V, by the switch 22'a.

One end of the secondary is earthed via the switch 23-'a, while the other end comprises a rectification-filtering device composed of capacitors 41, 42 and diodes 43, 44, 45, 46 and applied directly at the outlet 21a of the device 20, the other 21b being grounded. As for the control element, it includes a processing element 47 and a system determining the thresholds of the voltages U44, U24 and U31 which is formed by the three differential amplifiers 48, 49, 50 having a common input connected to the output 21a by l 'intermediate of the voltage divider bridge 51, 52, and another input connected to a reference voltage Vi via variable resistors 53, 54, 55.

 In operation, the switch 22'a loads the transformer 40. The voltage U10 corresponds to the closing of the switch 23'a, and the voltage U20 when it opens, since then the rectification-filtering device operates in double rectification sandwich course. The intensity is also adjustable by action on 34e and on amplifiers 37, 38.

 It is important that, in the case of switching means as illustrated in FIGS. 1 and 3, this switching does not deactivate the arcelectric triggered during the first phase of the process. To this end, the electromechanical relays illustrated by way of example in the drawings must also be fast enough, taking into account parameters such as the nature of the target (spacing of the conductors in particular), the extent of the fault and the structure of the device. location of this fault.

Otherwise, it goes without saying that these relays will have to be produced by means of electronic elements such as transistors and diodes according to arrangements well known per se.

 For example, given the large current intensities at the relay 24a-24b, it will preferably be produced by such electronic elements and will be controlled according to the current that the generator 24 injects into the line and which is detected by a resistor shown in Figure 3 at 56. The control element 26 will then react according to the voltage detected across the resistor 56 to control the relay 24a-24b or its electronic equivalent.

 Furthermore, the mounting of the generator 22, 23 illustrated in FIG. 3 facilitates the use of the electromechanical relays shown.

 It goes without saying that the present invention is in no way limited to the embodiments described which have been given for purely explanatory purposes. Consequently, all means equivalent to the means or embodiments described, modifications or variants of these means or embodiments also form part of the present invention as defined by the claims below.

Claims (5)

CLAIMS 1; Method for locating an insulation fault on an electrical line comprising at least two conductors separated by an insulator, of the type comprising the application of a high voltage to the line, characterized in that said high voltage is intended to initiate an electric arc between the conductors and has for this purpose a low intensity, and in that it consists, after the initiation of said electric arc, in reducing the voltage while increasing the intensity of the current as a function of the electric resistance of the line so as to melt said insulator at the location of the fault, then to weld the conductors together or to destroy at least one of them at the location of the fault.  2. Method according to claim 1, characterized in that the voltage decrease with increase in intensity is made in stages, successively comprising the application of a medium voltage of medium intensity intended to melt the insulator at the location of the fault and a low current of high intensity in order to solder the conductors between them.  3. Method according to claim 2, characterized in that the switching suc.cessive 'between said high, medium and low voltages is made when each of these voltages falls below a given threshold value.  4. Apparatus for implementing the method of claim 1, characterized in that it comprises means for generating variable voltage and current and control means reacting to the electrical resistance of the line to simultaneously vary said voltage from a maximum value å a minimum value and said current of minimum intensity & maximum intensity.  S. Apparatus according to claim 4, characterized in that the voltage generating means comprise three generators respectively delivering a high voltage of low intensity, a medium voltage of medium intensity and a low voltage of high intensity and in that the control means comprise means for switching these generators as a function of variations in the resistance of the line.  6. Apparatus according to claim 5, characterized in that the switching is made when each of said voltages falls below a given threshold value.  7. Apparatus according to claim 5, characterized in that the aforementioned switching means have a structure adapted to avoid any defusing of the arc during the course of the process.