DE10016557A1 - Cable fault locating device generates spark between contacts of main switch when fault is located to send current through electrode, resistor, pulse capacitor and decoupling and record fault in memory - Google Patents

Abstract

The contacts (8,9) of a main switch (10) are arranged in an air gap. The inductivity of a toroidal coil (5) due to a faulty location in a cable generates a spark between the contacts which closes the main switch and sends current through an electrode (7) and a resistor (11), discharging a pulse capacitor (12) and reflecting the fault on a decoupling (13), thereby recording the fault in a digital memory.

Description

The invention relates to a device for locating cable faults, especially for locating non-combustible cable faults in the range of branched cables according to the pulse reflection method, which is a loadable Has capacitor and a radio link that connects the capacitor to the Connects cable, and the a digital memory for recording the Storage of two measurement curves.

With the help of such a method and such a device it is in particular possible, a localization of high and medium impedance non-combustible cable faults. By discharging the Capacitor across the spark gap becomes a reflection wave in the area  the fault location of the cable generated from the distance to the fault location can be determined.

It is known to identify cable faults from high voltage pulses Locating capacitor discharges by displaying the reflection wave. The Usability of this method is determined by the ignition delay on the Fault location restricted. That is, the distance proportional to the error distance Runtime is extended unsatisfactorily by the ignition delay.

DE 41 00 305 A1 describes a circuit arrangement for localization high-resistance and intermittent cable faults using the pulse Echo method known. It is used in conjunction with a charging capacitor a shock wave generator for a shock wave on an air spark gap Ignition of the cable fault triggered.

They are also methods for pulse localization with high-voltage pulses become known in which by appropriate pre-ionization of the fault location the ignition delay does not take effect. These methods are in the German patent application DE 39 19 497 A1 described in detail.

The main subject of the published patent application DE 39 19 497 A1 relates a process in which the charging of a capacitor on the faulty Cable switched and an arc after the flashover at the fault location is produced.

If the capacitor voltage to a by the arc current certain value has decreased, is by short circuit of the current-limiting element impulses its residual charge on the faulty cables are discharged and the reflection wave generated in this way fed to a first channel of a digital memory for recording.

Before or after, a reflection wave is caused by a pulse voltage, which is less than the ignition voltage of the fault, i.e. a reflection wave without fault ignition, a second channel of the digital memory Record fed. By overwriting the records the fault location is determined for both channels. This method is suitable primarily for high-resistance and intermittent errors.  

Medium-resistance errors, however, such as those B. occur when the fault in There is water or has direct contact with the moist soil the current-limiting element has a voltage divider that measures the voltage Often reduced to so much that the fault no longer leads to ignition. The voltage across the capacitor therefore drops due to the current over the Leakage resistance to the pulse trigger voltage without one Fault has occurred. The digital memory records do not contain information about the fault location.

Furthermore, according to the prior art, a complex device for rapid short-circuiting of the current-limiting element is required. It must sufficient auxiliary energy to be provided for the switching process.

The capacitor of a shock wave generator serves as a pulse capacitor. These capacitors are designed for high energy density, but have not necessarily a low self-inductance. They are also called individual partial capacitors can be switched for several voltages. The cable connections to the changeover switch increase the effective inductance.

In the interest of high location accuracy, the slope of the But pulse as large as possible and thus the inductance of the circuit as possible be small.

The capacitor according to DE 39 19 497 A1 is used both for arcing as well as for pulse generation. As a result, only a part of the original charging voltage is available as pulse voltage. At difficult ignition conditions can be a disadvantage.

According to the German patent DE 43 35 924, the location quality increased in that parallel to a main capacitor in one Shock wave generator a second pulse capacitor is charged and the Main capacitor in the shock wave generator via a coil and the Pulse capacitor through a closed short circuit switch Close a main switch on which faulty cables are discharged and the resulting reflection wave via a decoupling first channel of the digital memory is supplied for recording and that after opening the short-circuit switch the main capacitor in Shock wave generator and the second pulse capacitor recharged and  then again by closing the main switch on the faulty cables are discharged, the discharge of the Impulse capacitor takes place over a plasma-triggered spark gap, the triggered from the charge of the shock wave generator via an ignition coil is, with a time delay in the plasma formation and Deflection a discharge pulse of the second pulse capacitor Defect point in the cable reached after the ignition has already taken place resulting ignition delay-free reflection wave via the decoupling a second channel of the digital memory is fed for recording and this by evaluating deviations of both Recordings by converting the respective pulse reflection times into Distance values of the fault location is determined.

Furthermore, according to DE 43 35 924, a device of the type mentioned in the introduction specified such that the localization of high and medium impedance cable errors is facilitated.

This object is achieved in that a shock wave generator with a Main capacitor is provided, one of which is connected directly and the other other connection via a coil and a main switch with the cable is connected that a second pulse capacitor via a contact is connected directly to the cable together with the main capacitor and via another contact via a short-circuit switch and the Main switch is connected to the cable with a spark gap a trigger electrode and main electrodes is provided, the Trigger electrode via an ignition coil, which is magnetically coupled to the coil is at a junction of the main capacitor, the coil and one Charging resistor of the second pulse capacitor is connected and the Short circuit switch as short circuit switch for the main electrodes is formed and that via a decoupling, a digital memory to a Lead of the second pulse capacitor is connected to the second Pulse capacitor connects to the cable.

Differing measurement profiles are thus generated, which are characterized by a Superposition and an evaluation of the signal differences an exact location of the cable error allowed. This takes advantage of the fact that Ignition delay different pulse reflection times depending on breakdown condition of the cable.  

A modification with a low leakage resistance of the cable and one hereby caused voltage division between the inductive Resistance of the coil and the leakage resistance, which prevent a Fault ignition can result in that at closed short circuit switch a reflection wave on the coupling a first channel of the digital memory is supplied for recording and then the charging voltage of the shock wave generator and the Charging voltage of the pulse capacitor to the maximum possible voltage is increased and the capacitors with the short-circuit switch closed discharged to the faulty cable by closing the main switch and that the reflection wave via the coupling device a second Channel of the digital memory is fed for recording and then the recordings of both channels are written on top of each other in such a way that an occurring point of deviation of both records is a location further away than the actual fault location is detected, and that another Localization in the direction of a cable start is carried out.

An improvement in slope to ensure accurate Locating can be done in that the pulse capacitor has a low Has self-inductance. For this purpose, the pulse capacitor can be coaxial or be made at least face-to-face.

With a sufficiently high voltage of the shock wave generator It is also a guarantee of a safe ignition of the spark gap possible that the ignition coil and the coil as a single component are trained.

An appropriate electrical dimensioning is achieved in that the Loading resistor has a dimensioning such that at a Charging the pulse capacitor the voltage on the pulse capacitor the voltage at the main capacitor follows and that a sufficient Decoupling the pulse capacitor and the main capacitor at rapid unloading process is realized.

The ignition device specified in DE 43 35 924 is relatively complex. The This applies particularly if the surge voltage range is chosen to be very large got to. In order to achieve a reliable ignition even with small surge voltages, the gear ratio between the two coils must be very large  become. With high surge voltages, this is a costly insulation necessary. In addition, the higher the gear ratio Current over the spark gap smaller. The ignition behavior of the Main spark gap worsens.

In addition, at the moment of ignition, both coils become parallel switched. The inductance and thus the current and current flow time are then not more clearly determined. In the interest of optimal reflection on the The point of overlap in the cable is the current at the moment of ignition be as large as possible.

The object of the invention is the ignition device of the aforementioned Kind of simplify and improve so that the ignition also in large Surge voltage range works without restriction and so with the To connect inductance, which determines the current flow time, that the Pulse capacitor with the largest possible current, but after the Traveling wave is discharged onto the cable.

The object is achieved in that a main switch for Discharge of a surge capacitor, this can be one commercial impact switches act with an additional ignition electrode is provided, which correspond to DE 43 35 924 with a pulse capacitor is connected. This is loaded from the main capacitor.

Between the main capacitor and the main switch there is a ring coil Air gap executed inductance switched. It is arranged so that the contacts of the main switch in the coil axis direction are in the air gap.

If the main switch is closed, the main capacitor will discharge Ignition of a fault in the cable with a damped vibration. On The contacts of the main switch result in a strong spark and Plasma formation. The coil creates a strong magnetic field perpendicular to the Main switch contacts. The plasma is directed towards the ignition electrode deflected, thereby discharging the pulse capacitor onto the cable.

The inductance of the coil determines the current flow time. It also creates a magnetic field for plasma deflection The force exerted on the plasma  exercised depends on the current and on the induction in the air gap and there and then the current also determines the induction, from the square of the current.

By suitable arrangement of the ignition electrode, it can be inventively achieve that the ignition is roughly approximated at the current maximum. The According to the invention, the inductance of the coil can be dimensioned such that the Current maximum is reached shortly after the traveling wave has subsided and approximates the discharge ignition for the Impulse capacitor takes place. That is, the inductance of the coil is calculated the oscillation formula from the capacitance of the main capacitor and the Cooldown of the traveling wave in the given use cases is less than 500 usec.

A small inductance is advantageous with low bleeder resistances Cable. The higher current of a smaller inductor also contributes to one stronger spark and plasma formation.

In an embodiment of the invention, it is proposed that the toroid should not be like generally used as a multi-layer coil, but several in series to arrange switched individual coils on an insulating ring. This will each coil only with a part of the number corresponding to the number of coils Surge voltage applied. That reduces the isolation problems and is easier to manufacture. Such coils are commercially available as filter coils.

According to the invention, the device can also be installed in a shock generator become. The shock switch of the shock generator is then with a additional ignition electrode for discharging the pulse capacitor. This saves a second main switch.

In the drawings, an embodiment of the invention is schematic shown. Show it:

Fig. 1 The basic circuit diagram with the essential electrical elements.

Fig. 2 and 3 shows the basic mechanical structure in two views.

As known from DE 43 35 924, a pulse capacitor ( 12 ) from a main capacitor ( 2 ) is charged via a resistor ( 4 ). If the main switch ( 10 ) is actuated, the main capacitor ( 2 ) is discharged via a ring coil ( 5 ) after igniting the fault in the cable ( 14 ). The contacts ( 8 , 9 ) of the main switch ( 10 ) are located in the air gap of the ring coil ( 5 ). The plasma which forms as contact sparks when the main switch ( 10 ) is closed is deflected by the magnetic field of the coil ( 5 ) in the direction of an ignition electrode ( 7 ). The spark gap between the ignition electrode ( 7 ) and the contacts ( 8 , 9 ) from the main switch ( 10 ) ignites. Pulse capacitor ( 12 ) discharges onto the cable ( 14 ).

The other elements are known from function and dimensioning from DE 43 35 924. ( 11 ) is a resistor of the order of magnitude of the characteristic impedance of the cable ( 14 ) and is used to suppress multiple reflections.

Fig. 4 shows the integration of the device in a shock generator ( 1 ), wherein an impact switch ( 3 ) is provided with an ignition electrode ( 7 ) and takes over the function of the main switch ( 10 ), which can be saved as a result.

Claims (4)

1.Device for locating cable faults, in particular for locating non-combustible faults in the area of branched cables according to the pulse reflection method, in which a main capacitor is discharged via a main switch and an inductance by arcing and arcing at a fault location of a cable. A second pulse capacitor is charged parallel to the main capacitor and discharged in the arc generated by the main capacitor and the reflection of this discharge is recorded with a digital memory, characterized in that the inductance is designed as a ring coil ( 5 ) with an air gap, the contacts ( 8 , 9 ) of the main switch ( 10 ) are in this air gap, so that the plasma which arises when the main switch ( 10 ) is closed by the contact spark is magnetically moved in the direction of an electrode ( 7 ) such that the spark gap between the contacts ( 8 , 9 ) of the main switch ( 10 ) and electrode ( 7 ) ignites and the pulse capacitor ( 12 ) is discharged via a resistor ( 11 ) onto the cable ( 14 ) and the error reflection is coupled out via a coupling ( 13 ) for recording by a digital memory. 2. Device according to claim 1, characterized in that the inductance of the coil ( 5 ) is dimensioned such that the first current maximum of the discharge oscillation immediately follows the decay of the traveling wave, the greatest deflection force then being exerted on the plasma and the spark gap directly between the ignition electrode ( 7 ) and the contacts ( 8 , 9 ) of the main switch ( 10 ) ignites and discharges the pulse capacitor ( 12 ). 3. Apparatus according to claim 1 and 2, characterized in that the coil ( 5 ) consists of individual coils which are arranged in series arranged in a ring, whereby the coil ( 5 ) is easier to manufacture and the insulation can be made cheaper. 4. Apparatus according to claim 1, 2 and 3, characterized in that the device is permanently installed in a shock generator ( 1 ) and the impact switch ( 3 ) of the shock generator ( 1 ) is provided with an ignition electrode ( 7 ) and the function of the main switch ( 10 ) takes over, which can be saved.