DE3544508A1 - Combined transducer for measuring current and voltage simultaneously on pipe-sheathed conductors - Google Patents

Abstract

This transducer comprises only one transducer element. The transducer element consists of a Rogovski coil which is surrounded by a metallic, non-magnetic shielding. Inside the pipeline surrounding the current-conducting conductor, the transducer element is arranged in a groove in the radial plane to the conductor insulated from the inside wall of the pipeline. The metallic shielding simultaneously forms a capacitor both with the pipe and with the conductor, the two capacitors jointly forming a capacitive voltage divider.

Description

Subject of the invention

The invention relates to a combination converter for measuring current and / or voltage on pipe jacketed Ladders.

State of the art

The difficulties with the measurement of Current and voltage on tube-coated conductors is characterized by that both because of the high-voltage conductor as well as the compact design of modern high-voltage systems (due to the high insulating ability of the used Dielectrics such as gas dielectric with higher strength as air, e.g. B. Sulfur hexafluoride gas (SF6 gas); Solid dielectric, e.g. B. Polyethylene (PE); Mixed dielectric, e.g. B. oil-paper) a current and voltage measurement by means of directly displaying measuring devices is not possible.

Combination converter for simultaneous known Measurement of current and voltage on pipe jacketed electrical conductors such. B. for gas-insulated metal encapsulated High-voltage systems, use that for current transformers Transformer principle, which means that the current carrying Is surrounded by an iron ring, which is connected to a Winding is provided. Because of the magnetic coupling between the live conductor, iron ring and winding in an ammeter connected to the winding Current displayed that is proportional to the phase current.

A capacitive method is used for voltage measurement in such a way that one in the field space opposite the outer tube insulated measuring electrode is brought. Because of the capacitive coupling between conductor, measuring electrode and outer tube shows a between measuring electrode and outer tube attached tension meter the tension between conductor and Metal encapsulation.

In addition to those specifically for compressed gas-insulated, metal-encapsulated High voltage systems developed combination converters (e.g. DE 28 14 115 A1) there are combination converters for air-insulated High voltage systems where current and voltage transformers each work according to the transformer principle. Both converters are arranged in a common housing and thus form the combination converter.

While in the combination converters described so far for both current and voltage measurement own converter is required, the current transformer works according to the transformer principle, there is also Solutions that only need a converter. For example proposed (DT 24 57 797 A1), in the course of the current-carrying Switch on a resistor and turn on the to supply him with the voltage of a coil Magnetic field forms from which a Hall element Measuring voltage is obtained, which is proportional to the measured Phase current is. At the same time, due to the capacitive  Coupling of the measurement setup with the conductor at a suitable one Set a measuring voltage that is proportional to the Voltage of the conductor to earth.

Another, so far in practice for this measurement task The current measurement option that is not used provides the Rogowski coil. Rogowski already used a method in 1912 magnetic voltage measurement (archive for electrical engineering 1st vol., 4th issue, 1912, pp. 141-150) and reported in a subsequent article (Archiv für Elektrotechnik 1st vol., 12th issue, 1913, pp. 511-527) Current measurement using the magnetic voltmeter, the is commonly referred to today as the Rogowski coil, explained.

Other publications by other authors then dealt with the use of the Rogowski coil
- measurement of high quasi-stationary currents,
- measurement of lightning currents or
- Measurement of pulse currents.

Despite many suggestions, their use as a transducer remained but mainly on the current measurement Arc furnaces or for pulse current measurement in high energy physics limited.

The function of the Rogowski coil results from the fact that a long cylindrical coil, tightly wound on a flexible, non-magnetic carrier, is placed in a ring around the current-carrying conductor for current measurement as a closed coil, see FIG. 1. By the magnetic field emanating from a quasi-stationary current voltages are induced in the individual windings, which add up to a measuring voltage which in turn is proportional to the amplitude and the time derivative of the current. Since currents flowing outside the loop area also induce voltages in the Rogowski coil, suppression of these voltages is necessary. This is done, for example, by means of a counter-rotating winding closely connected to the Rogowski coil and connected in series with it. In order to protect the Rogowski coil from electrical fields, a metallic, non-magnetic shield is required, which is slotted along the Rogowski coil. This avoids circular eddy currents that would otherwise falsify the measuring voltage.

The solutions described have disadvantages, which are highlighted below:
Current transformers, which form the measurement signal only by means of the inductive properties of the transformer elements and do not take the capacitive into account, only deliver a satisfactory measurement signal within a relatively small frequency range, namely from the mains frequency to ten to twenty times the mains frequency; higher-frequency current components are suppressed by these transformers . If iron is contained in the magnetic circuit, a saturation effect occurs above a limit current, which falsifies the measurement. The same applies to voltage converters that only use the inductive properties of the converter.

Use of these converters in gas-insulated, metal-enclosed High voltage systems is questionable if next to the simultaneous acquisition of quasistationary currents and Voltages also rapidly changing currents and voltages to be recorded and registered, such as this during switching operations occur. So it is known that in particular the use of vacuum switches caused wave processes , which in turn are brief current and voltage increases cause an impermissible strain of Parts of the system and thus a risk to the entire system cause. A current and voltage measuring device for transient current measured variables should therefore be able to also to record currents and voltages, their frequency spectra reach into the megahertz area.

The use of the Rogowski coil in the described Form is only suitable for measuring quasi-stationary currents, because no precautions to suppress unwanted wave processes were hit like this when measuring quickly variable currents to avoid measurement errors required are.

In addition to the technical disadvantages, they are known to date solutions become very space-consuming, so that in itself very compact and therefore space-saving, gas-insulated, metal-enclosed high-voltage systems due to the Transducers require a larger volume than without them.

The same applies to the use of the combination converter in cable systems, Cable sleeves, terminations or bushings, where a small size is also important. Of course, these converters should also be in the Be able to reliably transient currents and voltages in appropriate Convert measuring voltages.

It is therefore an object of the invention to provide a combination converter build up of both quasi-steady streams and / or quasi-stationary voltages as well as transients Currents and / or transient voltages can be recorded the converter is built from a small, compact element is.

Solution of the task and its mode of action

The solution of the problem is that the Combination converter from only one converter element, which consists of a Rogowski coil made of a metal, non-magnetic Shield is surrounded, which is within the insulated pipeline surrounding the live conductor against the inner wall of the pipeline in a radial plane Conductor is arranged in a groove, and the metal shield both with the pipe and with the Conductor forms a capacitor, the two capacitors together form a capacitive voltage divider.  This design has the advantage that in the magnetic circuit no iron is used and therefore no saturation effects occur. Weight and size of this combination converter are so small that it is in existing components of the High-voltage system can be integrated, or later can be installed without much effort.

The solution to the problem can still be improved by that the coil start and coil end each have a resistor, the size of which is the characteristic impedance of the coil-compensation winding arrangement corresponds, with the beginning of the compensation turn or end of the compensation turn connected will. The compensation winding itself is caused by the metal outer shield of the Rogowski coil formed.

A further improvement of the invention can be achieved by that the mechanical installation of the combination converter is simplified by using an insulating Support ring is fixed within the pipeline, or through other measures such as B. clamping in a groove, is fixed. Fixing with an insulating support ring, which in turn z. B. glued to the inside edge of the pipeline has the advantage that with subsequent installation of the combination converter no groove in the already installed Pipeline needs to be incorporated into what the downtime the high-voltage system significantly reduced.

Also can be used in the manufacture of the piping a groove can be provided for the connecting flanges, so that if necessary, the converter at the points where it is needed can be installed without much effort.

The invention is based on drawings and Examples explained in more detail:

A circular coil with only one winding layer ( 1 ) is produced from a thin, enamel-insulated wire, the windings touching each other and the beginning of the coil touching the end of the coil, see FIG. 2. The coil can be increased on a flexible to increase the mechanical stability or rigid plastic carrier ( 2 ) can be applied. The coil is surrounded by a non-magnetic, longitudinally slotted, overlapping metal foil ( 3 ), the beginning of which coincides with the beginning of the coil and the end with the end of the coil, but the ends must not touch, see Fig. 3. The metal foil is opposite the Coil isolated. The coil start and coil end are each connected to the metal foil start or end via a resistor, the size of which corresponds to the characteristic impedance of the coil-metal foil arrangement, see Fig. 4.An insulated conductor leads from the coil start and the metal foil start to a transfer point at which the Measuring voltage between the two conductors can be tapped. The measuring voltage corresponds to the time differential of the conductor current.

The metal foil ( 3 ) enclosing the coil is in turn surrounded by a metal ring ( 7 ) or a ring which is provided with a metal coating so that the two parts are insulated from one another, e.g. B. by an insulating ring ( 8 ), see Fig. 5. From the metal ring ( 7 ) also leads an insulated conductor ( 9 ) to the transfer point at which the two conductors ( 5, 6 ) from the coil ( 1 ) and Metal foil ( 3 ) end. Between this conductor ( 9 ) and the conductor ( 5 ), which leads to the metal foil ( 3 ), there is also a measuring voltage that is proportional to the voltage that is present between the current-carrying conductor ( 10 ) and the metal ring ( 7 ) .

The operation of the combination converter in the current measurement is based on the fact that the magnetic field emanating from the current-carrying conductor ( 10 ) induces a voltage in the individual turns of the circular coil ( 1 ), which runs as a traveling wave both at the coil start and at the coil end. Since the coil start and coil end are each terminated with their wave resistance, the waves are absorbed there and cause a change in the voltages there. The resulting course of these voltages over time, z. B. the measuring voltage at the beginning of the coil corresponds to the differential of the conductor current, so that the original course of the conductor current can be recovered by means of a subsequent integration. This relationship has been demonstrated experimentally in a test circuit, see FIG. 7. The abbreviations used to designate the various components have the following meaning: HT high-voltage transformer, GL rectifier, C capacitor, IF spark gap, R resistor, L inductor, Kw combination converter, Rm measuring resistor, oscilloscope. The results are shown in FIG. 8, namely that partial image ( 17 ) shows the current of the current-carrying conductor and partial image ( 18 ) shows the measuring voltage for the current supplied by the combination transformer, and partial image ( 19 ) shows the course of the current recovered by subsequent integration. However, integration is not always necessary. B. not in the measurement of quasi-stationary, sinusoidal currents, as are common in electrical power engineering.

The fact that the metal foil ( 3 ) surrounding the coil ( 1 ) forms a capacitor both with the current-carrying conductor ( 10 ) and with the metal ring ( 7 ) surrounding the metal foil ( 3 ), results in two capacitors connected in series, which form a capacitive voltage divider with respect to the voltage between the current-carrying conductor ( 10 ) and the metal ring ( 7 ). The measuring voltage occurring between the metal foil ( 3 ) and the metal ring ( 7 ) is proportional to the voltage that prevails between the current-carrying conductor ( 10 ) and the metal ring ( 7 ).

Use of the combination converter

The combination converter is preferably used in single-phase, gas-insulated, metal-enclosed high-voltage systems, in cable terminations or in cable sleeves. He let can be manufactured with little effort and can be integrated into existing ones  Systems can be retrofitted.

In Fig. 6 the use of the combination converter in a gas-insulated, metal-encapsulated high-voltage system is shown as an example. Similarly, as shown in the schematic diagram of Fig. 5, the shielded with the metal foil (3) coil (1) is disposed coaxially around the current carrying conductor (10) and is held by a to exploiting Dende in the outer metal tube (11) groove (12). So that this arrangement is insulated from the outer metal tube ( 11 ), which corresponds to the metal ring ( 7 ) in Fig. 5, the groove is lined with an insulating layer ( 13 ), see Fig. 6. This insulating layer ( 13 ) corresponds to the insulating ring ( 8 ) in FIG. 5. The insulated conductors ( 5, 6 ) emanating from the coil ( 1 ) and the metal foil ( 3 ) are led to the outside through a gas-tight bushing ( 14 ) and end at the transfer point, the z. B. can be a terminal block. In addition, the conductor ( 9 ) is electrically connected to the metal tube on the inner edge of the metal tube and is also led outward through the gas-tight bushing ( 14 ) to the transfer point.

The quasi-stationary current and the quasi-stationary voltage can be measured directly by means of two measuring devices ( 15, 16 ) which are connected to the transfer point. Other possibilities for measuring voltage processing are to supply the measuring voltages either directly or via an amplifier to a control room, to convert them into light signals and to transmit them via optical fibers, or to digitize them and then to process them further. These and other possibilities are left to the respective application.

Meaning of the different figures:

Fig. 1 Use of the Rogowski coil for current measurement

Fig. 2 coil ( 1 ) on plastic carrier ( 2 )

Fig. 3 with metal foil ( 3 ) shielded coil ( 1 )

Fig. 4 Enlarged view of the coil ( 1 ) closed with resistors ( 4 ), and connection of the lines ( 5, 6 ) to the coil ( 1 ) and metal foil ( 3 )

Fig. 5 schematic diagram for the use of the combination converter on a tube-coated conductor

Fig. 6 Use of the combination converter in a gas-insulated, metal-enclosed high-voltage system

Fig. 7 test circuit for testing the combination converter

Fig. 8 oscillogram
( 17 ) - the current of the live conductor,
( 18 ) - the measuring voltage for the current and
( 19 ) - the integrated measuring voltage

Claims (5)

1. Combination converter for measuring current and / or voltage on tube-sheathed conductors, characterized in that the combination converter consists of only one converter element, which consists of a Rogowski coil, which is surrounded by a metal, non-magnetic shield, which is within the current-carrying Conductor surrounding pipeline is insulated from the inner wall of the pipeline in a radial plane to the conductor in a groove, and the metal shield simultaneously forms a capacitor with both the pipe and the conductor, the two capacitors together forming a capacitive voltage divider. 2. Combination converter according to claim 1, characterized in that the coil start with the start of the compensation turn and the coil end at the end of the compensation turn about a resistor the size of which Characteristic impedance of the coil-compensation winding arrangement corresponds to be connected. 3. Combination converter according to claim 1 and 2, characterized in that the metal surrounding the Rogowski coil Shielding the task of the compensation turn with takes over. 4. Combination converter according to claim 1 to 3, characterized in that the combination converter within of an insulating support ring, the support ring in the pipeline by gluing or by other means is fixed. 5. Combination converter according to claim 1 to 3, characterized in that the combination converter in prepared Connection flanges is installed.