HU197101B - Method for detecting trace between accessible terminal or earth fault and supply or known terminal of power cable under voltage and/or for detecting phase of conductor given at wanted place of line sector between accessible terminal and supply terminal, as well as loading device with a two-pole of periodically variable impedance suitable to the implementation of the method - Google Patents

Abstract

The method according to the invention can be used in particular to determine the pathways of wires in a shielded place with a metal casing and to identify a wire phase. The method according to the invention is that, at the accessible terminal of the power line, a vibration circuit tuned to the fifth or seventh harmonic of the network, or a load having an impedance of up to 100 ohms, is applied between the phase and ground conductor or two phase conductors, with one half-a-half of the current flowing through the network. the fifth or seventh harmonic, or the second or fifth subharmonic, is interrupted, and the strength of the harmonic or harmonic component of the field strength is measured in a manner known per se by electromagnetic field strength measurement. For determining the phase of the conductor of the current line according to the invention at the desired location,

Description

The method of discovering the path of a conductor with a short to ground fault according to the present invention is to search for or construct a star-point potential clamp at a transformer or known location of the wire, applying a dashed current between said terminal and a ground potential terminal.

The present invention further relates to a bipolar load device having a periodically varying impedance which interconnects a series impedance (52) and a switching device (54), and a neutral switching circuit (56) connected to a control input of a switching device (54) and a zero (58).

The present invention relates to a method for determining the path between an accessible terminal or a short to ground of a live power line and a known terminal of a live power line, and / or to determining a phase conductor at a desired location of a wire section between an accessible terminal and a power terminal preferably for carrying out the procedure. The process according to the invention comprises running wires, cables, etc. in a housing, especially in a shielded area with a metal cover. It can be used for exploring the path of the pipeline and for determining the phase of the current flowing through these pipelines or for the earth leakage path of the pipeline, and as such it can be used especially in buildings and reconstruction. The bipolar load device of periodically varying impedance, which is a further object of the present invention, is advantageously used as a load in carrying out the process. Eljárás In the process of exploring the path of a power line according to the invention between a power terminal and an accessible terminal, a load terminal is connected to the accessible phase conductor terminal of the line, optionally splitting the current flowing through the load and amplitude and electromagnetic field the points where one of the extremes of the field strength is obtained are connected. In the method of discovering the path between a ground fault in a power line according to the present invention and a supply or known terminal, a star point potential terminal is selected at the supply terminal or known terminal or, in the case of a single-phase system, or by inserting a load between the formed terminal and a ground potential terminal, dividing the current flowing through the load and measuring the magnitude of its electromagnetic field strength along the surface and connecting the surface points where one of the extremes of the field strength is obtained. The method of determining a phase conductor of a wiring section between the accessible terminal of an energized power line of the present invention and a phase conductor having a known phase has a load applied between the available neutral conductor and a phase conductor terminal, and measuring electromagnetic field strength and the maximum value of the electromagnetic field strength at the power terminal is assigned to the phase conductor of the geodetic current.

In buildings, plants, etc. equipped with high-current electrical equipment. in many cases for a variety of reasons, such as carrying out work, maintenance, renovation, building diagnostics, mapping of operating equipment, standardization, fire protection reviews, monument reconstruction, etc. Because of this, it is often necessary to determine from which distribution point, which circuit, which circuit-breaker or fuse (s) you are operating from, and where the power cord, cable, etc. comes from. the exact location of which may be indicated by the available single-line wiring diagram. It is also difficult if, due to a failure, it is necessary to discover the exact location of the wires and branch boxes. In addition, it is often necessary to determine the path and connection of the building's power-shielded power supply cable to the main power supply cable in the public area, as well as the route of the main power supply to the building. The task may be to select a particular cable from a wiring harness, and in some cases to select a grounded cable from an earth fault. Furthermore, as is known, the use of electricity can be made more economical by symmetricizing phase loads, so it is necessary to determine which phase is or is to be supplied to a single-phase consumer, installed or to be installed, for symmetrical distribution of consumers between phases.

There are many solutions available to accomplish these tasks.

Thus, voltage signaling devices, usually integrated with a metal crescent, are known for tracing a power line. These devices detect capacitance at 50 Hz generated by live power lines. They have the disadvantage that they signal at multiple voltage power lines at each line and their junctions. These devices can only be used to determine the phase that supplies an accessible terminal of a particular wire when the power is terminated individually by disconnecting the phases one by one, which is usually unwanted. Exploring the path of a given wire is done by locating and connecting the maximum values of electric field strength, but this results in a clear result only when all other wires are mostly undesired, and at the same time between the accessible terminal and the power terminal

-2197 101 also results in simultaneous, usually unwanted, discovery of all branches.

No. 357,634 is known. Wire Identification Device, which includes a transmitter and a receiver, as detailed in the AT patent. The transmitter is powered by a high frequency r; It has an oscillator which generates a high frequency signal and modulates it with an identifier with a frequency of several kHz. Your receiver includes an inductive sensor, a high frequency amplifier, a demodulator, a bandpass filter and a low frequency amplifier as well as an optical or acoustic display device. In its application, the modulated carrier frequency signal is applied by capacitive or inductive coupling to an accessible line or terminal of the wire to be identified. The search for the path of a wire is performed by searching and interconnecting with the receiver the maximum field strength areas of the electromagnetic field generated by the identification signal. The disadvantage is that, apart from the trace between the accessible terminal of the wire and the power terminal, all branches of the wire are exposed at the same time, which is undesirable and disproportionately increases the opening time. A further disadvantage is that the device is unsuitable for the purpose of determining the phase of a current in a given line, because the phase of the current in the line can only be identified by individually disconnecting the phases at the power terminal.

Also known as so-called. pipe and track finding instruments such as TT-2160 (manufactured by Telmes Instrumental Cooperative, Budapest), 81027 and 81018 (manufactured by Robotron, Dresden, NDK) and T 16/8 (manufactured by Robotron, Dresden, NDK) : HDW Elektronik, Kiél, GDR). These devices have a transmitter with their own power supply or a power supply that is independent of the mains power supply and incorporates a power generator of a frequency other than the mains frequency, and a receiver comprising an inductive sensor and a measuring or acoustic display actuated therewith. For trace search, the transducer current generator, by galvanic or inductive coupling, forces current into the path to be explored at the accessible terminal or wire section and traces the path by determining the maximum field strengths of the electromagnetic field generated by the applied current. These instruments are of limited use in the case of live wires, as they indicate at the junctions of the wire, or even at intersections with non-live metal objects, such as pipelines, both along the electrical line and in the pipeline. the current applied to the wire is shorted through the earthed metal components of the cable assemblies and cable connectors and, after some earthed assemblies or cable connectors, the electromagnetic field strength falls below the detectable level. Further tracking of the trail can only be achieved if the transmitter is moved to the other side of the excavated cable connector, so that the trail can be traced only intermittently and therefore lengthy. Furthermore, these devices provide an opportunity for proper application in determining the phase of a current flowing in a wire due to the propagation of the current forced into the wire through the couplings between the wires.

It is also known to determine the path and phase of live wires using the T 16/889 converter product (manufactured by Howaldtswerke GmbH, Kiél, Germany), which is accessible between the phase and the neutral conductor at the investigated path to be explored or to be determined. It includes a converter that transmits to and receives a 9.8 kHz frequency signal from a power source to be recorded, and a 9.8 kHz frequency electromagnetic field receiver. When using this device, the converter is inserted between the accessible terminals of the test wire, whereby the 9.8 kHz signal produced by the converter is superimposed on the voltage on the wire. It is only of limited use for trail detection because the 9.8 kHz signal extends in all directions at each junction of the wire and due to capacitive couplings and consumer attenuation, the strength of the magnetic field generated by the signal drops rapidly below the detectable level as it moves away from the accessible terminal. . The phase of the test wire can only be determined if the power terminals with known phases are within the size of the accessible terminal of the test conductor in which the 9.8 kHz signal is still detectable.

It is also known as the "Current Tracer" (manufactured by Pasar Inc., Denver, Colorado US). There are two variants of this device, one for a non-power cable and a T10 type encoder and receiver that requires a network-independent earth, and the other for a live wire with variable impedance to be inserted between the mains phase conductor and a grounded terminal or ground. It contains 25 types of load and receiver, where the frequency of the signal generated by the transmitter and the frequency of variable impedance load are more than 100 times the network frequency (6.25 kHz) and the minimum value of the variable impedance load is 1000 ohms. When using the device, one of the transducer or load terminals is connected to an accessible phase conductor terminal of the test wire, and the other terminal to a transducer is a network-independent earth terminal and under load to a grounded terminal or neutral. In the case of a power-free line with the receiver, the line through the load and the power supplied by the encoder at the accessible terminal at the accessible terminal and in the earth-closed loop at the earth terminal of the wire or under voltage the strength of the 6.25 kHz component of the electromagnetic field generated by the current flowing through the earth or the neutral conductor loop3

B

genes are detected and searched for locations of maximum field strength and conductivity, both for trail exploration and phase search. The disadvantage of this device is that the series inductance between the accessible terminal of the wire and the ground at the power terminal or intermediate earth and the capacitance between this wire and ground as they are frequency dependent impedances, compared to the value measured at the mains frequency is 6.25 kHz. and the capacitance represents impedance of less than one hundred. Therefore, the current of the 6.25 kHz signal applied to the wire or generated by load variation will appear at every branch of the wire under consideration, which is connected to the load under load, which has a significant inductance and capacitance, or is in operation and grounded. may be defined together with the simultaneous exploration of these branches.

Further, in the case of a power line, when searching for a path, to ensure that electromagnetic fields which are uniformly gelled by a phase conductor and a neutral conductor within a common enclosure are superposed to superimpose each other and produce a perceptible amount of electromagnetic field. This is a problem for a grounded, non-conductive system protected by a zero contact protection circuit, since independent grounding is not always possible due to the multiple earthing of the neutral conductor, and a load between the phase conductor and ground cannot be applied immediately disconnects the network part. This limits the applicability of the device.

Also known is the EOR 2 type device (manufactured by Gossen GmbH, Erlangen, Germany), which includes a load and sensor unit and is suitable for selecting a short to ground in a compensated power network. The load is placed between the star point of the network and the earth. The load is realized by a capacitance which is connected through a serial switch in parallel to the inductive compensation coil and is switched at a frequency of 0.3 Hz. Thus, the inductive compensation current is varied with the capacitor current at a frequency of 0.3 Hz. With the sensing unit used to select the earth leakage line, a change of 0.3 Hz in the magnetic field generated by the current in the earth leakage line is detected inductively. The disadvantage of this compensation-sounding earth leakage detection method is that it cannot be used for the detection of a grounded wire path in the compensated network, and neither for the selection of the grounded wire nor the path detection for the compensated network because the 0.3 Hz capacitive current superimposed Outside of its surroundings, due to the very low frequency, on the one hand it does not produce a signal to be evaluated in the inductive sensor of the sensor unit and on the other hand the magnetic field 4 of the magnetics induces a misleading voltage signal in the inductive sensor of the sensor unit. It is also not suitable for in-service wiring for the same reasons.

In addition to the individual drawbacks of the solutions described, a common drawback is that when the wire passes through an electromagnetically shielded enclosure, or through interfering electromagnetic fields, it is not applicable to path tracing or phase identification.

Thus, it has become a task to find a solution that enables the trace of an accessible power line between the accessible terminal and the power terminal, regardless of the enclosure's length and regardless of the distance of the accessible terminal from the power terminal. el, and finding a solution that can be successfully applied to accessible phase-conductor and neutral conductor terminals, or two-phase conductor terminals, and to any type of network protection solution, such as a wire protected by an earth leakage circuit breaker, and in network or high frequency electromagnetic fields. it is also easy to apply when tracing a stretch of wires. A further task, in accordance with the foregoing, is to find a solution for determining the phase of an unknown terminal accessible terminal during operation, or for selecting a grounded cable from a grounded cable or for determining a path.

Analyzing the drawbacks of the described solutions, it has been found that they result from the selection of a test signal generated on the wire for a high frequency signal. This high frequency results in effective shielding of conventional enclosures, and the signal propagates through power capacities and consumers representing inversely decreasing impedance in proportion to the change in frequency relative to the mains frequency, not only to the power supply, but also to the branches. which is also facilitated by an increase in the impedance of the wires in series with the frequency, which results in a very narrow field of perception of the electromagnetic field generated by the signal.

The present invention is based on the fact that by producing a test signal, the above-mentioned disadvantages can be avoided, for which the capacitance of the wire practically does not result in a decrease of the signal level, and the impedance of the serial inductive elements is negligible.

It is an object of the present invention to provide an electromagnetic field scanning signal of low or fixed frequency and detectable magnitude suitable for our purposes, which can be produced without interrupting the operation of the mains and is only substantially present in the wiring section between the power terminal and the accessible terminal. . Our measurements at an accessible terminal of a wire have shown that in the resistance of a loop formed by a phase and md conductor starting from an accessible terminal and terminating through a grounding at the power terminal, the transformer at the power terminal is virtually short-circuited. and in a loop closed through consumers, consumers are represented by their ohmic resistance. Thus, if the network is supplied with a low-frequency signal at the accessible terminal, the current at the transformer at the supply terminal will have a significantly higher current through the minimum impedance than in the loop formed by the other branches. In the line section between the accessible terminal and the power terminal, a higher level of current can also be generated by applying a short-circuit or near-short-circuit load at a given frequency to the available terminal. This allows the signal level of the test signal to be set so high that the result of the (asymmetric) electromagnetic fields excited and superimposed by the phase and zero or two phase conductors in a common housing or adjacent to each other and connected via the windings of the transformer noticeable.

Furthermore, by measuring the electromagnetic field generated by the mains current with a frequency analyzer, it was found that there is an outstanding maximum at 50 Hz, a lower but substantial maximum at 250 Hz, and minimum at 480 and 525 Hz, and not in the frequency range above 2 kHz. perceptible component. Thus, in our experiments, it has been found that if a short-circuit load is applied at an accessible terminal of the network, a considerably higher harmonic current flows between the power terminal and the accessible terminal than at the other branches. In the same way, by applying a load at the power terminal, an additional current increase can be generated on the conductor with a short to ground in the direction of the short to ground.

The disclosure of the present invention provides a method for overcoming or avoiding the above shortcomings and disadvantages, and a means for practicing the method.

Thus, in a first embodiment of the present invention, determining a path between an accessible terminal and a supply terminal of a live power line is connected to an accessible phase conductor terminal, and measuring the magnitude of the electromagnetic field along a surface and we get, we connect. The procedures of this first variation is by connecting another terminal of the load on the access terminal of one phase conductor or a known manner a zero conductor, as a load of the alternating voltage frequency of up to seven, preferably five, tuned to harmonic of series resonant circuit ⁸ we use, and in measuring the electromagnetic field strength of we appreciate the harmonic component of the electromagnetic field generated by the current flowing through the vibration circuit.

In a second embodiment of the present invention, determining a path between an accessible terminal and a power supply terminal of a live power line is connected to an accessible phase conductor terminal, the current flowing through the load, and the magnitude and magnitude of the electromagnetic field where we get one of the extreme values for the field strength, we connect it. The object of this variant of the method is to connect the other terminal of the load to the accessible terminal of another phase conductor or to the neutral conductor known per se, using up to 100 ohms impedance as standard load, and for a period of up to a seventh, preferably a fifth, for a period of up to a seventh of its half-waves, for a period of up to a seventh, preferably for a fifth, of its polar half-waves; and measuring electromagnetic field strength on the electromagnet the magnitude of the harmonic component or subharmonic component of the incident space.

In a third embodiment of the present invention, in determining a path between a ground fault in a live power line and a power terminal or known terminal, a star-potential terminal is selected or provided at the power terminal or known terminal; Load is applied between x> cs and the earth potential terminal, the current flowing through the load is interrupted, and the magnitude of the electromagnetic field is measured along the surface and the surface points where one of the extremes of the field strength is obtained are connected. The essence of this method of the invention is that during the measurement of the electromagnetic field strength, the interruption of the current flowing through the load during one of the polar half-waves of the second or fifth subharmonics of the alternating voltage is carried out we measure the magnitude of the fifth subharmonic component.

In a fourth embodiment of the present invention, in determining a phase conductor at a desired location of a conductor section between an accessible terminal of a live power line and a power terminal having known phases, a load is applied between the accessible phase and zero conductor terminals.

measuring the field strength, and assigning the current field leading to the maximum field strength to the current conductor that produces the maximum value for the electromagnetic field strength at the power terminal. The essence of this variation of the method is to load up to a seventh, preferably fifth, series oscillating circuit of the frequency of the alternating voltage, and at the desired location and at the power terminal, the electromagnetic field generated by the electromagnetic field generated by the current through the oscillation circuit.

In a fifth embodiment of the present invention, determining a phase conductor at a desired location of a conductor section between an accessible terminal of a live power line and a power terminal having known phases involves applying a load between the accessible phase and neutral conductor terminals, measuring the field strength and assigning the maximum field-strength-current phase conductor to the electromagnetic field strength at the power terminal with a maximum value for the field-conducting phase conductor. The essence of this variation of the method is to use a load of up to 100 ohms impedance measured at the base harmonic, and for a period of up to one seventh of the polar half-wave duration of the current flowing through the impedance or a defined subharmonic, preferably a second or fifth subharmonic, of an alternating voltage is interrupted during periods of one of its polar half-waves for periods outside the periods of its alternating half-waves of the same polarity, and measure the magnitude of the harmonic component or subharmonic component

With respect to the embodiments of the present invention, any available network element having two phase conductive terminals, such as a socket outlet, a terminal block, and the like, has a desire for an accessible terminal. You can form. Power supply terminal, transformer secondary voltage terminal, distribution rail, consumer connection point, etc. can form

In carrying out variations of the track discovery method of the present invention, the electromagnetic field strength measuring device, known per se, is moved in a known manner by sweeping along the surface. The extreme value is the maximum position or the minimum between two adjacent maximum positions.

In carrying out embodiments of the present invention, a variety of devices can be used to selectively measure the subharmonic component of electromagnetic field strength and selectively measure the field strength component at the desired subhannonic frequency. A device suitable for this purpose also comprises an inductive sensor coil, an amplifier and filter unit connected directly to the output of the inductive sensor and a comparator connected to the output thereof, and a light and acoustic means operated from the output of the comparator. The amplifier and filter unit can be adjusted to adjust the sensitivity of the device. The filter consists of low-pass filter members and bandpass filters which pass through the frequency range below the fundamental frequency.

In carrying out embodiments of the present invention, the load current is interrupted at a desired rate with an impedance of up to 100 ohms, appropriately selected and connected at the appropriate subharmonic rate of the mains frequency. A further object of the present invention is to provide a bipolar load device having a periodically varying impedance frequency for this purpose, which comprises a series connected impedance and a switching device, in particular a thyristor, a frequency divider circuit and a switching device connected to the switching device. a zero transition switching circuit, the output of the frequency division circuit being zero transition; is connected to a blocking input of the switching circuit, and one of the poles of the bipolar load device is connected to one of the impedance terminals by the first input of the zero-switching circuit and the first input of the frequency divider and the other terminal of the switching device. input and the second input of the neutral (switching circuit).

A common outstanding advantage of the process variants of the present invention is that the electromagnetic field excitation current generated for path tracing or phase identification is generated by a voltage generator but by a non-interfering operation of a specified component of the live line current. A further advantage is that since the sensed electromagnetic field is subharmonic, 25 Hz or 10 Hz, or low-order harmonic, 250 Hz or 350 Hz, conventional shields are less effective in this frequency electromagnetic field than the high frequency electromagnetic fields used in known methods. , which also allows you to trace the paths behind the electromagnetically shielded enclosures.

A further advantage is that since relatively low frequency current is used to scare the electromagnetic field, current flows through the line between the power terminal and the accessible terminal due to the impedances represented by the capacities of the junctions and increased at low frequency compared to the mains frequency. distance · can be explored independently. Another advantage is that by providing a relatively low frequency electromagnetic field, this field can be measured with sufficiently good selectivity, and thus our process variants can be used in an environment disturbed by electromagnetic fields.

-611

It is also an advantage over the known methods that while the known methods are applicable only in the presence of phase and zero conductor or earth potential terminals, the variants of the invention can also be used in the presence of two phase conductors and in networks protected by an earth leakage circuit breaker.

An advantage of the inventive method of discovering the path of a conductor with a short to ground fault is that it can be used in both compensated and insulated star point gratitude, for example in power plants.

It is a further advantage that the power on / off switching of the load during the implementation of the process variants, since the on and off moments are at the time of the zero harmonics current, do not disturb the operation of telecommunication and other equipment such as computers.

The invention will now be described in more detail with reference to its embodiments, and with exemplary loads and characteristic waveforms that may be used for such embodiments, with reference to the accompanying drawings, in which:

Fig. 1 is a one-line view of a power network component with power terminals, hubs, serial fuses, multiple outlets, multiple accessible terminals, consumers, and two locations where the phase of the current in the line can be determined; the

Fig. 2A is a power line image of a conductor extending across a surface and of the electromagnetic field generated by the conductor, as well as a distribution of the field strength when axially moving a sensor coil with a possible line position;

Fig. 2 / b is a diagram of a line extending across a surface and of the electromagnetic field generated by the line, as well as the distribution of the field strength for axial movement of the sensor coil with another possible line position; the

Fig. 3 shows a block diagram of a tuned oscillating circuit for use as a load for carrying out the embodiments of the present invention in position with a load loaded with a conductor; the

Fig. 4 shows the waveform and its components of a current flowing in a line loaded with a fifth harmonic tuned oscillating circuit shown in Fig. 3; the

Fig. 5 is a block diagram of the impedance applied to the load of the method variants of the present invention and its current-chopping switching device; the

Fig. 6 shows the waveform of the current generated by applying the impedance shown in Fig. 5 for the interruption of the impedance current in a fifth harmonic; the

Fig. 7 is a block diagram circuit diagram of a bipolar load device having a periodically varying impedance for use in the embodiments of the invention; the

FIG. 8 is a representation of the impedance of FIG. 5 or FIG. 7 of the present invention. In the case of a 12 bipolar load device as a load and in the case of a second subharmonic (25 Hz) interruption

a) waveform of the basic harmonic current,

b) a waveform of the current flowing through the load; the

(c) the waveform of the current in the load line and

d) a waveform of the signal output at the output of a filter member tuned to a second subharmonic component of the electromagnetic field; the

Fig. 9 is a method of applying the impedance of Fig. 5 or the bipolar load device of Fig. 7 as a load in the methods of the present invention, and in the case of a fifth subharmonic (10 Hz) interruption;

a) waveform of the basic harmonic current,

b) the waveform of the current flowing through the load, a

(c) the waveform of the current in the load line and

Fig. d) a waveform of the signal output from a filter member tuned to a fifth subharmonic component of the electromagnetic field; the

Figure 10 illustrates solutions for connecting a bipolar load device shown in Figure 7 to a network for exploration of a live line with a short to ground voltage with an earth fault in an unknown location;

Figure a) Power supply from a transformer with a star point,

Fig. b) in the case of a mains supply from a delta circuit transformer via a voltage transformer,

Fig. c) for a network fed from a single-phase transformer.

Fig. I shows a single line view of a power network component with a grounded star power supply transformer 4, a power supply rail 5 connected to the secondary side of the transformer 4, branching conductors 6, 7, 8 and 9 connected to each rail 5, 18, where each branch fuse 19A, 19B, 19C included in each of the branch conductors 9a, 9b, 9c forms a power terminal 10 with known phases.

The branching main line 9 is connected to a consumer terminal rail with a known phase R, S, T phase conductor and a neutral conductor 0, from which a power line comprising 22, 26 and 30 phase conductors and 21, 25 and 29, respectively, and a branching power line 31 34, 37 accessible to consumer locations with staples. The phase conductors 22, 26 and 30 of the power lines are equipped with a short-circuit breaker 11, 12 and 13, respectively. The figure also shows the consumers representing the operating load 32, 35 and 38 connected to the network at each of the accessible terminals 31, 34 and 37, respectively.

In the figure, the trigger 13 is designated as the desired location for phase identification.

As a first example of a more detailed description of the route exploration method of the present invention, the

· The exploration of a high-voltage power line containing a wall of neutral conductors 29 and a phase conductor 30 extending in an unknown location leading from the mourning to the place of mourning.

In the first version of the path discovery method, a vibration circuit 51 tuned to a fifth harmonic (250 Hz) of the mains AC frequency is applied as a load 50 between the available terminal terminal 37 and the neutral terminal terminal. Installation of the 51 resonant circuit as a result, as a result of the coordinated of the line current form for the fifth harmonic of a short circuit, as illustrated in Figure 3 through flow I ₃₁ is superimposed alaphartnonikusú l _3t) current flow associated with the same 37 accessible terminal 38 operating load. Thus, in the loop terminated by the neutral conductor 29 and the phase conductor 30 at the accessible terminal 37, there is a current bo in the loop up to the power terminal 10, which has the characteristic fifth harmonic wave superimposed superimposed on FIG. Accordingly, the electromagnetic field generated by the current ₃₀ also has a fundamental harmonic and a fifth harmonic frequency component.

Starting from the available terminal 37, the path is explored using a fifth harmonic tuner to search for surface points at which an extreme value of electromagnetic field strength is measured.

Depending on the position of the power line inside the wall, two extreme values can be measured in extreme cases. If the plane defined by the neutral conductor 29 and the phase conductor 30 is parallel to the plane of the wall, axially displacing the measuring coil of the measuring apparatus to obtain a field distribution E with a maximum curve, the power line extends below the maximum field strength points 2. /the. Figure 6 is a sectional view.

If the plane defined by the neutral conductor 29 and the phase conductor 30 is perpendicular to the plane of the wall, by moving axially perpendicular to the conductor of the meter coil, two near maxima, including a curve with a minimum, are distributed below the power line. as in Fig. 2 / b. Figure 6 is a sectional view.

The points with extreme values of electromagnetic field strength, due to the fifth tuned configuration of the measuring device, are obtained only along the power line, so that their connection gives the desired path.

In this way, the path of the power line leading to the accessible terminal 37, indicated by the dotted line in FIG. 1, is obtained up to the power terminal 10.

For example, if an accessible terminal 34, for example, has a terminal with only a phase conducting terminal, as indicated in dashed in FIG. 1, one terminal of the load 50 is connected to this phase terminal and the other terminal to another,

197 101 is connected to, for example, a neutral conductor or a phase conducting terminal at accessible terminal 31, whereby the accessible terminal 34 can be traced from the accessible terminal 34 and the trace of the power line supplying the accessible terminal 31 from the accessible terminal 31.

The trace of the power line can be traced even when the load is the Seventh Harmonic Vibration Circuit. In this case, the current flowing through the oscillation circuit is smaller due to the characteristics of the network, and thus the strength of the electromagnetic field is lower, so that the extremes are searched with more careful measurement and the seventh harmonic tuning device.

In the second version of the trace exploration method of the present invention, the load 50 is an impedance 52 which has a resistance of up to 100 ohms when measured at a basic harmonic value.

Similarly, the impedance 52 is inserted between the neutral conductor 29 and the phase conductor terminal 30 at the accessible terminal 37, or if the accessible terminal has only one terminal as indicated by the dashed line in FIG. 1, the accessible terminal 34 is the terminal of the phase conductor 26. another example, inserted between the terminal of the neutral conductor 21 at the accessible terminal 31 or the terminal of the phase conductor 22.

When the impedance 52 is connected to the accessible terminal 37, the loads applied to the accessible terminal 37 are indicated by the currents flowing through them, as shown in Figure 5. To interrupt the current flowing through the impedance 52, the switching means 54 is connected in series with the impedance 52.

In the first embodiment of this version of the path discovery method, the dream flowing through the impedance 52 is interrupted by switching means 54 during periods of one of the polar half-waves of the basic voltage of the mains voltage to the intervals of the fifth harmonic half wave. This results in superimposition of the current 1 _J2 to the basic harmonic operating current I ₃₈ flowing through the load ₃₈ during one of the fifth harmonic semiconducting flows of impedance 52, thereby providing a substantially current generator-like current I ₃₀ at the accessible terminal 37. which is well detectable up to the supply terminal 10. Route determination is performed as described above, starting from an accessible terminal 37 fed from the power line to be explored, using a measuring device tuned to the 250 Hz component of the electromagnetic field as described above. Connecting the excavated points of the electromagnetic field with the highest value gives the desired path

Alternatively, this method may be implemented by interrupting the current flowing through the load 52 for periods of half-waves of the same frequency as the seventh harmonic (350 Hz) of the mains frequency. Due to network capacity, this week8

· -8s -

197101 The 16th harmonic current is already spreading considerably, so the extremes of the electromagnetic field it generates are determined by a longer measurement and a seventh harmonic tuner.

In the second embodiment of this second embodiment of the present invention, tracing the path is performed by interrupting the impedance current 52 through one of the second or fifth half harmonics of one of its polarities to a time interval other than or equal to the second harmonic, to its fifth harmonic component by searching for points with a field strength of extreme value. The subharmonic tuner to be measured is used for the search.

Similarly, the desired path is obtained by connecting points with extreme values of electromagnetic field strength.

The impedance 52 and the switching means 54 for interrupting the impedance 52 in one of the polar half-waves of a defined sub-voltage of the mains voltage for periods other than the periods of the basic harmonic half-waves are preferably of two periodically variable impedances.

The block diagram of the bipolar load device 60 with periodically varying impedance is shown in Figure 7. The bipolar load device 60 has an impedance 52 of up to 100 ohms as measured at its fundamental frequency and a switching device 54 connected in series, preferably a thyristor. The bipolar load device 60 further has a zero-switching circuit 56 which is a standard commercial product, such as an integrated circuit of the type CA 3058, CA 3059 or CA 3079; and a frequency divider circuit 58 which may be a count circuit, such as an integrated circuit of the FZJ 121 type or the like. The first input of the neutral switching circuit 56 and the first input of the frequency divider circuit 58 are connected, and connected to one of the terminals of the impedance 52 via this common terminal limiting resistor 59, they form one of the poles of the bipolar load device 60. The other pole of the bipolar load device 60, the other terminal of the switching device 54, such as the thyristor cathode, is formed in conjunction with the second input of the zero-transition switch circuit 56 and the second input of the frequency divider circuit 58. The output of the frequency divider circuit 58 is connected to the neutral input of the switching circuit 56, the output of the switching circuit 56 is connected to the control input of the switching device 54, such as the thyristor control electrode.

The measurement of the harmonic component of the electromagnetic field can be carried out with a variety of measuring devices. A preferred embodiment of the measuring apparatus comprises an inductive detector coil, an amplifier and filter unit directly connected to the output of the inductive sensor and a rectifier connected to its output, and a light and acoustic means operable from the comparator output. The amplifier and filter unit can be adjusted to adjust the sensitivity of the device. The filter consists of low-pass filter members and bandpass filters which pass through the frequency range below the fundamental frequency.

In the desired path line, the subharmonic frequency current component is produced by the bipolar load device 60 by plugging the bipolar load device 60 into the network, for example at an accessible terminal 37. The bipolar 60 is powered by the mains power required for its operation. The frequency divider circuit 58 disables the zero-shift switch clock 56 for the second harmonic (25 Hz) and the fifth harmonic (10 Hz) for the second and second (2.5 Hz) tuned to the desired harmonic component. When the zero-switching circuit 56 is disabled, the basic voltage of the mains voltage produces an ignition pulse at each of its zero-crossings. Since the anode of the thyristor implementing the switching device 54 is connected via the impedance 52 and its cathode is directly connected to the AC voltage network, the current generated in the line can be clearly seen in FIGS.

Figure 8 is a flow-through 38 ₃₈ 1 alapharmonikusú load current waveform in the accessible terminal to the 37) of the

(b) the waveform of the 60 bipolar load current flowing through the device in the event of an ignition being ignited every other period of the basic harmonic,

c) part of the former summation of currents due to line current I of line current waveform and _3C

d) In part, the waveform of the U ₂ voltage at the output of the filter member of the second subharmonic meter measuring the strength of the electromagnetic field is shown.

9 is a waveform of the basic harmonic current I ₃₈ flowing through a load ₃₈ , a b) a current waveform of the current currents flowing through the bipolar 60 during biased ignition every two 2.5 periods, due summation current I in the wire ₃₀ and current waveform d) portion of the electromagnetic field strength measuring device subharmonic fifth tuned filter member ₅ U appears at the output voltage waveform is shown.

As mentioned above, the subharmonic frequency current component flows through a winding of an accessible terminal, a power line, and a power transformer coil in a closed loop. In this way, the path of the power line can be traced from the available terminal to the power transformer, practically at a distance.

The path of a live conductor with an earth fault location at an unknown location is determined from the power supply terminal or known terminal by utilizing the fact that

-917 that the current component at a subharmonic frequency is less textual at the network junctions than at the subharmonic frequency. In this variant of the method, if the power transformer has a star point as shown in FIG. 10, an impedance 52 is connected between the star point and the ground potential terminal in series with the switching means 54 and by switching the switching means 54 a subharmonic component. we create a current that is superimposed on the basic harmonic current of the network. This can also be achieved by inserting a periodically variable impedance bipolar 60 device between the star point of the transformer 4 and the earth potential terminal.

When the transformer 4 is delta switched, a magnetic star terminal is provided at any known terminal of the wire through voltage transformers 53 and a two-pole load device 60 is inserted between this star terminal and a ground potential terminal 60. When the wire is single-phase, a two-pole load device 60 is inserted between a live terminal and a ground potential terminal as shown in FIG. 10c. illustrated.

The subharmonic plus earth leakage current flows in a loop formed by the wire, the earth fault, ground, and the bipolar load device 60. The tracing of the trace is performed as described above with a measuring device tuned to the subharmonic component of the electromagnetic field of the loop current, and at the end of the traced trace there is a ground fault.

In the case where, for example, the phase conductor 30 at the accessible terminal 37 or the fuse 40 at the desired location determines the short-circuit trip of the fuse 13, the network frequency is applied to the network 37, e.g. The harmonic or subharmonic component of the electromagnetic field is measured at the phase conductors 9a, 9b and 9c of the power terminal 10, respectively, and the phase conductor, the phase conductor, the phase conductor, and 13 short-circuit breakers.

Claims (6)

Claims 1. A method for determining the path of an energized power line between an accessible terminal and a supply terminal by applying a load terminal to the accessible phase conductor terminal, measuring the magnitude of the electromagnetic field along a surface, and obtaining at the surface points where coupling, characterized in that the other terminal of the load (50) is connected to an accessible terminal of another phase conductor or a neutral conductor known per se, the load (50) being up to seventh, preferably fifth, of the alternating voltage frequency and in measuring the electromagnetic field strength geijesztett by flowing through the resonant circuit (51) current (I ₅₁₎ electromagnetic field harmonic component méq'űk. ' (Priority: July 16, 1986) 2. A method for determining the path of an energized power line between an accessible terminal and a supply terminal by applying a load terminal to the accessible phase conductor terminal, interrupting the current flowing through the load, and measuring the magnitude of the electromagnetic field along and a field strength is obtained by connecting the other terminal of the load (50) to an accessible terminal of another phase conductor or, in a manner known per se, to a neutral conductor, using a load (50) of 100 ohms impedance (52) during duration measurement of flow through the impedance (52) (S _J2), the duration of the current or alternating voltage fundamental harmonic of one-polarity half waves of up to seven, preferably one fifth ik, its harmonic for periods of half-waves of the same polarity, or a defined subharmonic of alternating voltage, preferably second or fifth subunits _; harmonics, during the duration of one of its polar half waves, is interrupted for periods outside the duration of its alternating half waves, and the electromagnetic field strength is measured by the harmonic component or subharmonic component of the electromagnetic field. . (Priority: November 30, 1987) 3. A method for determining the path between a grounded fault of a live power line and a power terminal or known terminal by selecting or designing a star potential terminal at the supply terminal or known terminal, selecting a voltage terminal for a single-phase system, and load is applied, the current flowing through the load is interrupted, and the magnitude of the electromagnetic field is measured along the surface, and the surface points where one of the extremes of the field strength is obtained are connected, characterized by changing the flow through the electromagnetic field. the basic harmonic of the alternating voltage during the duration of one of the polar half waves of the second or fifth subharmonic voltage is the same polar and for the magnitude of the second or fifth subharmonic component of the electromagnetic field. (Priority: November 30, 1987) 4. A method for determining the phase of a conductor at a desired location of a line section between an accessible terminal of a live power line and a power terminal having known phases, -1019 197 101 in which a load is applied between the available phase and neutral conductor terminals, and an electromagnetic field strength is measured and the maximum field current generating phase conductor is assigned a maximum value of the electromagnetic field strength at the power terminal, voltage frequency of up to seven, preferably fifth harmonic of tuned series resonant circuit (51) is used, and the desired site, and the feeding terminal to the strength generated by current flowing through the resonant circuit current (I ₃₁₎ electromagnetic field harmonic component is measured. (Priority: November 30, 1987) 5. A method of determining a phase conductor at a desired location of a conductor section between an accessible terminal of an energized power line and a feeder terminal having known phases, comprising applying a load between the accessible phase and node conductor terminals, interrupting the current flowing through the load, and assigning a maximum field-conducting phase conductor to a current conductor with a maximum value for the electromagnetic field strength at the power terminal, characterized in that a load of up to 100 ohms impedance (52) is used as the load at baseline and up to the seventh, preferably fifth, harmonic of one of its polar half-waves s polarity half waves of durations between durations or of the alternating voltage subharmonic defined, preferably Co, ith or fifth subharmonic, the duration of one polarity half waves from outside of duration main periods of the alternating voltage _{of 5} ity fundamental harmonic with equal polarity half waves • interrupted, and at the desired location, and measuring the magnitude of the harmonic component or subharmonic component generated by the impedance current at the supply terminal. (Priority: November 30, 1987) 6. A bipolar load device (60) having a periodically varying impedance, preferably from 1 to 5. A method according to any one of claims 15 to 15, characterized in that it has a series connected impedance (52) and a switching device (54), in particular a thyristor, a frequency divider circuit (58) and a zero transition switch circuit (54) connected to its output. wherein the output of the frequency divider circuit (58) is connected to the neutral input of the neutral switching circuit (56) and one of the poles of the bipolar load device (60) is The first input of the switching circuit (56) and the first input of the frequency divider (58) are connected via a limiting resistor (59) to one terminal of the impedance (52) and the other terminal to the second terminal of the switching device (54) and the frequency divider ) and a second input of the zero-transition switching circuit (56).