DD157981A3 - MEASURING ARRANGEMENT FOR ELECTRIC STROEME - Google Patents

Abstract

1. Measuring arrangement for electric currents, comprising two transformers (1, 2) wherein the current to be measured flows through the primary winding (5) of the one transformer (1) and a current representing the current to be measured flows through the primary winding (6) of the other transformer (2), characterized in that each of the transformers (1, 2) includes a magnetic core and both have substantially the same transformation characteristic, that the secondary windings (3, 4) of both transformers are connected in parallel, and that an active four-terminal network (7) is connected to the juncture of the secondary windings (3, 4) said network being controlled by the difference between the currents of the secondary windings (3, 4) and driving the current in the primary winding (6) of the other transformer (2).

Description

Dr. Jochen Ermisch Dresden, on 22.11.

Prof.Dr.Werner Brendler -TNP / Oe / Di

IPK: G 01 R .1 / 20

217290

Measuring arrangement for electrical currents

The invention "relates to a measuring arrangement for electrical currentso this is especially for such currents'vorgesehen that can not be detected directly meßtech-nisch because of their strength and their potential.

Characteristic of the known technical solutions

Current transformers are used to convert high currents into those which are directly accessible for measurement. In a conventional design, these consist of the primary winding through which the current to be measured, the magnetic core and the secondary winding, which is terminated with a burden. The secondary winding performs a, corresponding to the primary current, determined by the transmission ratio current. However, the real ratio between primary and secondary current shows deviations, which are referred to as converter errors. Since the current measurement, however, requires a certain power consumption in the secondary circuit, the burden can not be chosen arbitrarily small. Small converter errors therefore require the corresponding consideration of other parameters influencing the error , a magnetic core with high initial permeability used «

 To reduce the converter error - through the

Material properties and technical design options put out frame, a variety of so-called art circuits have become known, which are designed either with passive or active elements.

Thus, an error-compensated transducer is known in which the burden-dependent losses are largely compensated (DE-AS 1 303 532). This is done by means of a feedback amplifier and an inductive coupling element. The coupling element represents a so-called magnetic simulation of the transducer, that is. The material of both magnetic cores has the same magnetization characteristic. By comparing the drive-dependent voltages of the transducers and inductive coupling elements, the amplifier additionally feeds the power of the internal burden of the converter into the converter and thus compensates for the occurring error. The amplifier thus does not cover the measuring power of the transducer · The actual transducer must therefore be dimensioned for the load to be applied. The need for the correct detection of higher short-circuit currents can also be taken into account only by increased material costs.

There are the / further current transformer with electronic error compensation, in which in the secondary circuit such a voltage is fed, that the induction in the converter goes to zero. Such a transducer is virtually independent of current and load changes in terms of fault behavior, because the burden of one Amplifier is applied and the converter is controlled in a constant magnetic operating point. Such current transformers, which are also referred to as current comparators, have a relatively high accuracy 'at low dead weight on o indicator windings or Hall probes are used as indicators for the disappearance of induction (DE-OS 2,632,377 and DE-OS 2,621,302) , It must

TuR file 1723 - 3 - 217290

However, constructive versions are selected, which have only a minimal scattering. Furthermore, it is not possible with this measurement principle to improve already installed, in-service current transformers.

Aim of the invention

It is an object of the invention to improve the measurement of electric currents for economic reasons.

Presentation of the essence of the invention

The invention has for its object to provide an arrangement for measuring electrical currents, in particular to high voltage potential, indicate that ensures a very high accuracy, even in the overcurrent range with low material usage. This object is achieved with the help of two magnetic cores exhibiting transformer of at least approximately the same transmission behavior, the secondary windings are connected together to form a circuit, the Pri-r märwicklung the first transformer of the current to be measured and the primary winding of the second transformer of a current is proportional to the current flowing through. Furthermore, working on the primary winding of the second transformer, an active quadrupole, which is controlled by a circuit taken from the secondary windings difference size. The active quadrupole is preferably designed as a differential amplifier and connected with its inputs to the connections of the two secondary windings For the detection of very high currents each transmitter is equipped with an additional second secondary winding. These additional secondary windings are connected in such a way that the one winding ends are galvanically connected and the other winding ends are connected to the inputs of the active quadrupole. Particularly favorable Gesta.ltungsmöglichkeiten and conditions of use arise in the formation of the first, traversed by the current to be measured transmitter, if this, as E.inleiterstromwandler

is designed with a toroidal core.

For the interests of DC measurement, an additional secondary winding is also provided for each transformer. These are fed by a frequency generator

For automated measurement sites and / or digital signal processing, the desired DC current magnitude mapping of the primary current can be advantageously achieved by connecting a rectifier bridge with DC indicator _s z, B, in the form of a Graetz bridge, to the primary winding of the second transformer is switched.,

In connection with the supervision of multi-conductor systems, it may be favorable to use the first transformer in the manner of a. Zero Current Transformer Training «

An optionally necessary potential separation between the active quadrupole and the AC indicator can be achieved in that a further transformer is provided, on which the active quadrupole operates and whose secondary winding is in series with the primary winding of the second transformer »'

embodiment

Reference to an embodiment of the invention will be explained in more detail. In the accompanying drawings show;

1 j the basic circuit of the measuring device according to the invention for electrical currents,

E ¹ Ig. 2: a control option for the differential amplifier,

FIG. 3: a measuring arrangement modified for direct current measurements, FIG.

Fig. 4: a measuring arrangement with an output _? which supplies DC signals, ''

Fig. 3 '' a measuring arrangement which has been modified in the manner of a zero-current transformer and

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Pig. 6: a measuring arrangement with potential separation between measuring circuit and differential amplifier.

FIG. 1 shows the basic circuit arrangement according to the invention. The measuring arrangement consists of two transformers 1, 2, whose secondary windings 3 4 are connected together to form a circuit. The primary winding 5 of the first transformer 1 is traversed by the current to be measured, while the primary winding 6 of the second transformer 2 is fed by a differential amplifier 7. The differential amplifier 7 is placed with its inputs to the two connections of the secondary windings 3; In series with the primary winding 6 of the second transformer 2 is a Wechselstromindikat'or 8 arranged Both exchanger 1, 2 have substantially the same transmission behavior, d _o h. They work with the same magnetic induction in their entire drive range.

If the primary winding B of the first transformer 1 is traversed by a current to be measured, the differential amplifier 7 outputs to the primary winding 6 of the second transformer 2, a current which is so large that between the two compounds of the secondary windings 3 ^ the voltage setting near zero. In both transformers 1, 2 there is now the same flux related to the length of the magnetic path. Since, according to the assumption, both transformers 1, 2 have the same characteristic and the currents in the secondary windings 3 are equal to 4, the current flowing through the primary winding 6 of the second transformer 2 must be proportional to the magnitude and phase of the current to be measured , Since the burden power is applied to the AC indicator 8 from the differential amplifier 7, the amount of burden has no influence on the transmission behavior of the measuring device., As long as the differential amplifier 7 can muster the measuring power. Preferably, the first transformer 1 in the manner of a Einleitwandlers with. Toroidal be executed, since this acts only as a signal generator without significant power transmission. In contrast to the current

In a conventional manner, the transformers 1, 2 can be designed with extremely low material expenditure, since the structural conditions justified on the basis of measuring technology and performance are eliminated. Both transformers 1 and 2 need only have the same characteristics. This condition is fulfilled if both converters are equipped with the same magnetic material, both converters in the nominal working range have the same values of induction and both transformers in the dimensioning primary current times primary winding number per average core path length -are"

FIG. 2 shows another possibility for the control of the differential amplifier 7. Here, both transformers 1, 2 each contain a further secondary winding 9 which can also be referred to as indicator windings. The indicator windings 9S10 are connected to their one winding ends and the other end to the windings is placed at the inputs of the differential amplifier 7 * By this arrangement, the differential amplifier 7 is controlled by the prevailing between two transformers difference of induction »This is a possibility that comes especially for high currents in question when the dimensioning of the transmission ratio between the current in The primary winding 5 of the first transformer 1 and the current through the secondary windings 3, 4 is problematic ο Also suitable for high currents in question, is an arrangement not shown in the drawings, in which the indicator windings zusammengesch together to form a circuit are old and the inputs of the differential amplifier are connected to the two connections.

FIG. 3 shows a circuit arrangement modified for direct-current measurement. Both transformers 1, 2 are each provided with a further winding 11, 12, which are fed by a frequency generator 13. As a result, a modulation is forced in the transformers 1, 2. Without current through the primary winding 5 of the first transformer 1, the amplitudes of the magnetic circuits of the transformers 1j2 are the same, that is to say they are equal to each other.

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the voltage between the terminals of the differential amplifier 7 is zero and no current flows through the primary winding 6 of the second transformer 2. With an additional modulation of the transformer 1 by a current in the primary winding 5, the voltage between the terminals of the differential amplifier 7 and It flows through the primary winding 6 of the second transformer 2, a current whose mean value corresponds to the S rom in the primary winding 5 of the first transformer 1 O

FIG. 4 shows a circuit arrangement in which the image of the primary current as a direct current variable is possible for use in automated measuring stations and / or for digital signal processing. For this purpose, the primary winding 6 of the second transformer 2, a rectifier bridge 14 is connected in series with a DC indicator 15. The rectifier bridge 14 may be implemented in a Graetz circuit ₀ Since, in order to produce a same injection point in the transformers 1, 2, a current must flow through the primary winding 6 of the second transformer 2, which is the current in the primary winding 5 of the first transformer 1 and is not determined by additional switching elements in the output circuit of the differential amplifier 7, the "current through the DC indicator 15 representative of the rectifying value of the AC current through the primary winding 6 of the second transformer 2 is independent of the characteristic curve the rectifier diodes used.

In connection with multi-conductor systems, it may be necessary to carry out the first transformer 1 in the manner of a zero-current transformer. According to Figure 5, the average, the magnetic Weg.-related flooding of the transformer 1 is generated by a plurality of current-carrying primary windings 16 of the first transformer Accordingly, the average, related to the magnetic path through the second transformer 2 by the current in the primary winding 6 " of the second "over *

tragers 2, i. the current in the primary winding corresponds to the correct-sign addition of the currents in. the primary windings 16 "

FIG. 6 shows a circuit arrangement in which a further transformer 17 is provided for potential separation between differential amplifier 7 and the measuring circuit. This is particularly advantageous if the measuring arrangement according to the invention is to be used in circuits where a plurality of measuring elements are present, but the amplifiers are galvanically connected via the auxiliary power source or if the amplifier arrangement is at a potential which is as high as the potential of the current to be measured as well as the potential of the representing current is different. The measuring circuit is thus galvanically isolated. It is also possible to apply the invention to current transformers already installed in plants. The relevant current transformer then represents the first transformer 1. As a result, in addition to an extremely improved accuracy, the Überstroinzahl the converter significantly increased.

Claims (2)

TuR file 1723 '- 9 - 2 17290 invention claim 1 measuring system for electrical currents, characterized in that it consists of two magnetic cores having transformers (1} 2) with at least similar transmission behavior, the secondary windings (3; ^) work against each other and their primary winding (5) of the current to be measured and whose other primary winding (6) is traversed by a current representing the current to be measured which drives an active quadrupole (7) controlled by a difference in the circle of the secondary windings Oj ^) » 2o measuring arrangement according to item 1, characterized characterized, the active quadrupole (7) is a differential amplifier, the input side to the compounds of the two secondary. windings (3 »4). 3o measuring arrangement according to item 1, geke nnzeichn et by the fact that the transformers (1, 2) each have a further secondary winding (9, 10)., Which are connected in such a way that the one coil ends are galvanically connected and the other coil ends to the , Inputs of the active quadrupole (7) are placed. 4o measuring arrangement according to item 1, characterized in that the from. Measuring current flowing through transformer (1) is designed in the manner of a single-ended current transformer with toroidal core. 5o measuring arrangement according to item 1, characterized in that "for the DC measurement, both transformers (1, 2) have a further winding (11, 12) which are fed by a frequency generator (13). 6. Measuring arrangement according to item 1, characterized in that in series with the primary winding (6) of the current flowing through the representative transformer (2)
AC indicator (8) and / or a rectifier bridge (14) with DC indicator (15) connected
is. 7 measuring arrangement according to item 1, characterized in that the transformer (1) through which the current to be measured is implemented in the manner of a zero-current transformer 8. measuring arrangement according to item 1, characterized in that a further transformer (1?) Fed by the active quadrupole is provided, the secondary winding of which is connected in series with the primary winding (6) of the transformer (2) through which the current is represented, Enclosed 2 sheets drawings