DE3812997A1 - Method for picking out a cable and a device for carrying it out - Google Patents

Abstract

In a method for picking out a low-voltage cable from a number of similar adjacently located cables, in which a characteristic current is impressed on the cable to be picked out and this current is verified with the aid of a preferably direction-sensitive clip-on ammeter at any point on the cable, and in which the neutral conductor of the cable to be picked out is connected to at least a second neutral or protective conductor and the cable to be picked out exhibits a feeding-in end and an open end, in order to provide for the cable to be picked out when it is under voltage, an external conductor is connected via a switchable load resistor to the neutral conductor at the open end of the cable and the resultant difference between external-conductor current and return current in the cable is used as the characteristic current.

Description

The invention relates to a method for reading a never the voltage cable from a number of similar, cont bart lying cable, with the cable to be read out characteristic current is impressed and this on egg is detected at any point on the cable, and at that of the neutral conductor of the cable to be selected with at least at least connected to a second neutral or protective conductor and the cable is an infeed and an open end having.

During repair work on electrical energy supply networks often has the task of consisting of several, in the correct cable for a cable duct i.e. to select the one in need of repair. In case missing the unique external identifier on the cable is the This task can only be solved with technical aids Lich.

For this purpose, devices are used that have the cable to be selected apply a characteristic signal to the the search point can be included and so the selection of the cable. For activated, i.e. tension Uncoupled cables are known to have two readout methods for example in the trade journal "Der Elektriker", 26. Vintage, issue 1/87. In one case a high frequency signal is applied to the cable and the electrical figuration around the cable Field evaluated. At another known Aus reading process is a sawtooth-like impulse on a Given the wire of the cable to be read and for example with the help of a direction-sensitive clamp meter grasslands.  

The well-known selection procedures are subject to serious consequences share that they can only be used for voltage-free cables are. During the activation of a medium voltage cable is usually possible without interrupting the supply the activation of a low-voltage cable almost always with an inconvenient or hardly portable supply interruption connected.

The invention is therefore based on the object, a Ver drive and to create a device for its implementation fen, with which is in operation, under Low voltage cables from neighboring lie have the same cables read out.

This object is achieved in that a method of the type mentioned at the open An outer conductor at the end of the live cable via a switchable load resistor on the neutral conductor is placed and the resulting difference in the cable between load current in the outer conductor and reverse current as characteristic tical current is used, which enables the selection.

The solution to the problem also includes one Switchable load resistance device for Implementation of the method according to the invention.

The invention takes advantage of the fact that low power cable networks for energy distribution to end users are usually operated as open radiation networks. It feeds in at one end of the cable, whereas the other re remains open. In addition, the neutral and Protective conductor functions in the entire network in one Head, the so-called PEN head summarized. These Circuit form is called TN-C network.  

By one between an outer conductor and the PEN conductor additional ohmic load resistance of the cable an additional load flows in the respective outer conductor electricity. The reverse flow belonging to this current does not flow only through the cable's own PEN conductor, but also through the PEN conductors of neighboring cables as well as other back river routes, such as the soil and underground pipes, as well as metal sheaths and / or shields of adjacent cables and Lines of other utilities, insofar as they are conductive and are grounded. Because the additional reverse current in the cable itself is therefore smaller than the additional outer conductor current, the resulting difference in the cable is unequal Zero and can therefore be detected with a clamp meter will.

The selection will be even easier and clearer if the Load resistance switched on and off periodically, i.e. is clocked, with which the serving as a read-out feature Difference between phase conductor and reverse current a character can be stamped with the identifier. When reading out Cable can find the identifier with high amplitude again the, whereas with all other cables due to the distributed return flows the same identifier only with essential Lich lower amplitude can be found again.

In one embodiment of the device according to the invention the clocking of the load resistance by a time control lais realized.

The Ver according to the invention can be particularly advantageous use drive if a rectifier in series with the Load resistor is switched. The additionally flowing Load current in the outer conductor then only flows in one direction,  i.e. it will be on the half waves of only one polarity limits, whereas all backflows into the other Flow towards. When using a directional sensor union current clamp attached to a center-zero instrument is then shown in the cable to be read characteristically clocked deflections only in one Direction, whereas with all other cables the pointers out strikes much weaker in the other direction gene.

Based on the schematic representation in the drawing who the further details of the invention explained. Show it:

Figure 1 is a schematic diagram of the basic circuit for performing the inventive method.

Fig. 2 shows the load circuit of a device according to the invention; and

Fig. 3 shows the control circuit of the apparatus of FIG. 2.

Fig. 1 shows a schematic representation of a low-voltage cable with a symbolically illustrated protective cover 1 , which comprises three outer conductors L ₁ , L ₂ , L ₃ and a combined protective and neutral conductor PEN. At the open end 2 of the cable, a load resistor R _L , a switch S and a rectifier D are connected in series between the outer conductor L ₁ chosen here as an example and the PEN conductor. The switch 1 is mechanically coupled with a clock generator t ₁ . An additional current I _L1 flows through the outer conductor L ₁ via the load resistor R _L. Not only is the cable's own PEN conductor available for the entire return current, but also several other return conductors 3 . The reverse current is therefore divided into several partial reverse currents I _R1 ... I _RN . The difference I _{L 1} - I _{R 1} in the cable can be detected with a clamp meter.

Fig. 2 shows an embodiment for the load circuit of a device according to the invention. Between a connection socket for an outer conductor of the cable to be read, for example L ₁ , and a socket for the PEN conductor of the same cable is the current path for the load current, formed from two contactless switches in the form of antiparallel thyristors T h ₁ and Th ₂ , two rectifiers D ₁ and D ₂ , three load resistors R ₁ to R ₃ connected in parallel, each with a contactless switch T h ₃ to Th ₅ connected in series and a current indicating instrument A. The switch ter T h ₁ and the rectifier D ₁ form the partial current path for the negative half-waves of the load current; Accordingly, the switch T h ₂ and the rectifier D _{2 form} the partial current path for the positive half-waves. By optionally switching on the load resistors R ₁ to R ₃ via the switches T h ₃ to Th ₅ , the amount of the load current which can be read on the display instrument A can be set.

Connected in parallel with the load current path are a transformer Tr for supplying the control circuit of the device shown in FIG. 3 and two motors M which drive a cooling fan (not shown here) for the load resistors. The motors M can be connected to voltage via a switch A ₁ . Between the switch A ₁ and the transformer Tr connected in series is a second switch ter A ₂ . Switching on the control circuit is therefore only possible while the cooling is running. Two control lamps L a ₁ and La ₂ are connected in parallel to the motors M and to the transformer Tr , respectively, and indicate the switching states of the switches A ₁ and A ₂ .

Three lines, each with a switch A ₃ to A _{5, are} connected between the socket L ₁ and the socket PEN, and three control lamps L a ₃ to La ₅ in series. The switches A ₃ to A ₅ are mechanically connected to the correspondingly designated switches in the control circuit. The control lamps L a ₃ to La ₅ signal the switching state of the contactless switches T h ₃ to Th ₅ and thus the level of the load current. In one embodiment of the device according to the invention, the load resistors R ₁ to R ₃ are dimensioned in such a way that the load current can be set in stages between 12A and 36A with an applied voltage of 220 volts.

In Fig. 3, the control circuit of the exemplary Darge device according to the invention is shown schematically. Between the control voltage supplied by the transformer Tr ( FIG. 2) there is a time switching relay t ₁ , which alternately applies the control voltage to the control connections of the antiparallel thyristors T h ₁ or Th ₂ . In this way, either the path for the positive half-waves of the load current or the path for the negative waves of the load current is enabled. In the exemplary embodiment of the device according to the invention, the switching times per polarity of the half-waves can be set between 2.5 seconds and 25 seconds. Parallel to the timing relay t ₁ are three control lines for the thyristors T h ₃ to Th ₅ with switches A ₃ to A ₅ . When one of these switches is closed, the respective thyristor switches through and releases the load current via the associated load resistance.

With the method and the device according to the invention its implementation will be a selection of live standing low voltage cables possible, which is of great advantage part in repair work on electrical power supply supply networks.

Claims (10)

1.Procedure for reading out a low-voltage cable from a number of similar, adjacent cables, in which a characteristic current is impressed on the cable to be read and which is detected at any point on the cable, and in which the neutral conductor of the cable to be read out with at least at least a second neutral or protective conductor is the and the cable to be read has a feed and an open end, characterized in that at the open end of the live cable an outer conductor is placed on the neutral conductor via a switchable load resistor and the difference in the cable between the load current in the outer conductor and reverse current is used as the characteristic current. 2. The method according to claim 1, characterized in that the load current on the half-waves of only one polarity is restricted.   3. The method according to claim 1, characterized in that the two flow directions of the load current in below different and characteristic clocked who the. 4. The method according to any one of claims 1 to 3, characterized characterized in that the level of the load current through Change additional load resistors in parallel is changed. 5. Apparatus for performing the method according to claim 1 with a load circuit and a control circuit, characterized by a load resistor ( R ₁ ) and a series-connected, contactless switch, the lying in the control circuit lying switch, in particular a timing relay ( t ₁ ), is controlled. 6. The device according to claim 5 for performing the method according to claim 2, characterized in that two rectifiers ( D ₁ , D ₂ ) each with a series-connected contactless switch ( T h ₁ , Th ₂ ) are connected to one another in anti-parallel. 7. The device according to claim 6 for performing the method according to claim 3, characterized in that the two switches ( T h ₁ , Th ₂ ) are alternately controlled by a time relay ( t ₁ ) located in the control circuit. 8. The device according to one or more of claims 5 to 7 for performing the method according to claim 4, characterized in that several with an elec tronic switching element ( T h ₃ Th ₄ Th ₅ ) connected in series GE load resistors ( R ₁ , R ₂ , R ₃ ) are connected in parallel to each other. 9. The device according to one or more of claims 5 to 8, characterized in that as a contactless Switches each have two anti-parallel thyristors be used. 10. The device according to one or more of claims 5 to 9, characterized in that the load or resistors ( R ₁ , R ₂ , R ₃ ) are cooled by a built-in fan.