RU2224262C1 - Instrument current transformer - Google Patents

Abstract

FIELD: precision measurement of currents in single-and three-phase high-voltage networks. SUBSTANCE: instrument current transformer has input and output current buses, divider of measured current from n current-carrying branches connected in parallel-four-pole shunts is connected in parallel to them. Resistive leads-out of shunts are connected to corresponding inputs of measurement module which output is output of current transformer. EFFECT: increased measurement precision, diminished level of magnetic leakage fields, reduced cost, mass and dimensions and raised reliability of transformer. 1 dwg

Description

 The proposed solution relates to electrical engineering and is designed to measure high currents in single and three-phase high voltage networks.

 High current sensors based on proportional current dividers are known, one of the links of which is the primary winding of a current measuring transformer, the secondary winding of which is connected to a measuring resistor or to the input of an electronic measuring module containing an operational amplifier, an analog-to-digital converter, and a microprocessor controller [1].

 The closest in technical essence to the proposed technical solution are compensation measuring current transducers, based on measuring current transformers, in which the primary magnetic flux is automatically compensated by a magnetic flux of the opposite direction, while the current creating a compensating magnetic field is strictly proportional to the input current and is easily measured [2, 3]. The disadvantage of such measuring current transducers is the difficulty of implementation for measuring high currents in high voltage networks.

 The proposed solution allows you to enhance the advantages and eliminate the disadvantages inherent in the well-known options for the construction of shunt and transformer current meters.

The technical result of the proposed solution is to improve the following technical and environmental characteristics:
- a significant expansion of the range of measured currents;
- improving the accuracy of measurement and reliability of the device;
- a significant reduction in cost, weight and dimensions;
- a significant decrease in the level of magnetic fields of scattering;
- the possibility of periodic verification with available metrological equipment.

 The technical result is achieved by the fact that in a measuring current transducer containing an input and output current bus, parallel to which is connected a divider of the measured current from "n" parallel-connected current-carrying branches - four-pole shunts, the resistive terminals of one of which are connected to the measuring module, the output of which is the output devices, said measuring module of the device contains "n" small-sized current transformers, divided by serial numbers into even and odd groups, in which The secondary winding of each current transformer is connected to the resistive terminals of the shunt according to its serial number and parity group, and the secondary windings of the current transformers of each parity group are connected in series and according to, forming two common windings that are closed to each other through the primary winding of the normalizing current transformer, the secondary the winding of which is connected to the differential inputs of an adjustable amplifier, the output of which is through the compensating winding of the normalizing transform A current switch and a measuring resistor are connected to the housing, and the connection point of the compensating winding with the measuring resistor is the output of the device and connected to the modulating input of the transmitter, the output of which is connected to the physical communication line, and the physical communication line of the receiver is connected through a series-connected receiver and control voltage generator with the control input of the adjustable amplifier, while the second input of the driver of the control voltage is connected to a source of adjustable voltage.

 In FIG. 1 shows a structural diagram of a measuring current transducer.

 The measuring current transducer contains input 1 and output 2 current buses, a measured current divider 3, consisting of "n" four-pole shunts 4 and a measuring module, consisting of "n" small-sized current transformers 6, each of which has a primary 5 and secondary 7 winding , normalizing current transformer 8 with primary 9, secondary 11 and compensating 10 windings, adjustable amplifier 12, measuring resistor 13, control voltage shaper 14, transmitter 15, receiver 16, transmitter physical communication line 17, device output va 18, physical communication line 19, a receiver 20, a regulated source voltage.

 The principle of operation of a measuring current transducer (IPT) is based on the possibility of maximizing the advantages of shunts and current transformers (CT) and eliminating or partially compensating for their shortcomings. This result can be achieved due to the optimal distribution of the measured current between the shunts and current transformers, for this the main current is passed through the shunts and only part of the current is branched into the primary windings of the current transformers. In addition, an increase in the number of shunts and CTs used can reduce the currents flowing through them by tens and hundreds of times and significantly improve their technical and environmental characteristics (reduce the CT scattering fields).

The measured current J _{0 of the} load of the power supply flowing through the buses 1 and 2, through the divider 3 of the measured current, consisting of a set of "n" parallel connected identical four-pole shunts 4 and through the primary windings 5 CT connected to the resistive terminals of each shunt can be defined as:
J ₀ = n (J _W + J _Tr ), (1)
where J _W - current flowing through the shunt,
J _tp is the current flowing through the primary winding of the CT.

где Z_ш - сопротивление шунта,
Z_тp - полное сопротивление первичной обмотки ТТ.Current J _tp is equal to

where Z _W - the resistance of the shunt,
Z _TP - impedance of the primary winding of the CT.

 K is the ratio of the total resistance of the primary winding of the CT to the resistance value of the shunt.

Так как величина К значительно больше единицы, выражение (3) примет более простую форму

где m - масштабный коэффициент, характеризующий долю тока J₀ в первичной обмотке ТТ.From expressions (1) and (2) we determine the current J _tp

Since the value of K is much larger than unity, expression (3) will take a simpler form

where m is a scale factor characterizing the fraction of current J ₀ in the primary CT winding.

 Obviously, the larger the coefficient "m", the less TT, the easier, more accurate, more stable and cheaper.

 For example, a decrease in current and angular measurement errors is directly related to a decrease in dimensions and an increase in the number of turns of the primary winding of a CT. In a small-sized CT, it is not a problem to realize a multi-turn primary winding with a thin wire.

 However, the above method cannot neutralize the harmful effect of the inductive nature of the resistance of the CT primary winding on the current measurement error, since the components of this error always have different signs: the current one is positive and the angular one is negative.

 This and a number of other problems of precision current measurement can be dealt with by compensating for the measurement error by the known method of anti-magnetization of CT cores.

 To do this, the secondary windings of all CTs are divided by serial numbers into even and odd groups and, within their parity group, they are connected in series, forming two common secondary windings from the "n" secondary windings (the even winding - conclusions "a" and "g" and odd - conclusions "b" and "c", Fig. 1), which are closed to each other through a low resistance of the primary winding of the normalizing current transformer (NTT).

 For brevity, the current of the primary windings of the CT and the magnetic field created by it are called primary, and the current of the secondary windings and the magnetic field created by it are secondary.

 The secondary current is limited by the resistance of the primary winding of NTT, however, the secondary magnetic field created by it is quite sufficient to compensate (anti-magnetize) most of the primary magnetic field, which contributes to a significant improvement in a number of technical characteristics of IPT.

 For example, anti-magnetization changes the nature of the resistance of CT primary windings from inductive to active-inductive with a predominance of the active component of the resistance, which significantly reduces the current and angular errors of measurement, significantly reduces the magnetic fields of scattering, eliminates the mutual influence of CTs, extends the range of measured currents, increases resistance to DC measured current, creates an additional opportunity to reduce weight and dimensions.

 Further processing of the current signal is as follows. When the primary current flows through the primary NTT winding, a proportional voltage is induced in its secondary winding, which is amplified by an adjustable amplifier (RU) 12 and supplied to the compensating NTT winding 10 and the measuring resistor 13, while the current flowing through the compensating winding 10 creates a magnetic field in NTT 8 opposite in direction to the magnetic field created by the current of the primary winding 9.

 The gain of RU 12 is quite enough to balance the magnetic fields created in the core of the NTT by the currents of the primary and compensating windings in all measurement conditions. This is a prerequisite for the ideal operation of an AC transformer, which allows you to realize a high accuracy class and measurement stability.

 A measuring resistor 13 connected in series with the compensating winding 10 NTT serves as a simple current-voltage converter.

 The resistance of this resistor determines the steepness of the current-voltage characteristics of the conversion of the primary current of the NTT to the output voltage of the IPT, taken from this resistor. At the same time, this voltage is supplied to the modulating input of the transmitter, which, through a selected physical (radio frequency, optical, infrared, etc.) communication line 17, transmits current information about the parameters of the measured current to a remote measurement recording and recording point.

 Calibration, and, if necessary, verification, IPT is carried out by changing the transfer coefficient of RU 12 by the driver 14 of the control voltage.

 Shaper 14 at one of its inputs is controlled by the output voltage of the receiver 16 of remote control commands received at its input via any selected physical communication line 19, and at the other control input of shaper 14 is carried out directly by changing the voltage level of source 20.

 The inclusion of the transmitter 15 and the receiver 16 in the IPT structure allows to control the technical characteristics and significantly expand the functionality of the device. So, for example, by combining the receiving and transmitting physical communication lines with a computing tool, it is possible to optimize the technical parameters of the IPT and turn it into an exemplary measuring tool, into an energy quality analyzer and a command generator of operational relay automation for protecting electric networks and electrical equipment.

 Thus, the IPT measuring module turns a simple shunt current divider 3 into a precision multifunctional metrological measurement tool.

 The quality of high-voltage insulation is completely determined by the quality of insulation of the primary winding 9 NTT 8 (points "a" and "b" in figure 1). This winding is wound with a wire with high voltage insulation. There are no other elements with increased insulation requirements in the module.

 The design of the measuring module can take any form convenient for placement and connection to the resistive terminals of shunts 4.

 For operation in an unfavorable or aggressive environment, additional sealing of the measuring module is ensured by filling with epoxy resin in a vacuum environment.

 The measuring module can be connected (and disconnected) with the resistive terminals of the shunts 4 of the current divider 3 through the connector (it is better if it is with zero articulation force) and then it can be removed, for example, for verification (without breaking and disconnecting the main current circuit) with a special device removal and installation of the module. This is a completely safe procedure without compromising the reliability of the entire measuring system.

 The parameters of conventional current transformers, such as the nominal ultimate magnitude of the primary current, electrodynamic and thermal resistance, and resistance to short-circuit currents in the measuring module are not so critical due to a significant reduction in the forces of their generating.

 The proposed technical solution in comparison with the prototype allows to increase the measurement accuracy; expand the range of measured currents; significantly reduce the level of magnetic losses of scattering fields; significantly reduce the cost, weight and dimensions and increase the reliability of the measuring current transducer.

Sources of information
1. US patent 4492919, IPC G 01 R 1/20, H 01 F 40/06, 01/08/95.

 2. Current transformers. Afanasyev V.V., Adonyev N.M., Kibel V.M. et al. - L.: Energoatomizdat, Leningrad Branch, 1989, Ch. 2, p. 47-57.

 3. Current transducers for measurements without breaking the circuit. Andreev Yu.A., Abramzon G.V. - L .: Energy, 1979, ch. 2, p. 48-52.

Claims (1)

A measuring current transducer containing input and output current buses, in parallel with which a measuring current divider is connected from n parallel connected current-carrying branches - four-pole shunts and a measuring module, characterized in that the measuring module contains n small-sized current transformers, divided by serial numbers into even and odd groups in which the primary winding of each current transformer is connected to the resistive terminals of the shunt corresponding to it in the parity group and serial number eu, and the secondary windings of the current transformers of each parity group are connected in series and according to, forming two common secondary windings that are closed to each other through the primary winding of the normalizing current transformer, the secondary winding of which is connected to the differential inputs of the adjustable amplifier made, the output of which is through the compensating winding of the normalizing a current transformer and a measuring resistor is connected to the housing, and the connection point of the compensating winding with the measuring resistor The rum is the output of the device and is connected to the modulating input of the transmitter, the output of which is connected to the physical communication line, and the physical communication line of the receiver is connected through a series-connected receiver and control voltage generator to the control input of the adjustable amplifier, while the second input of the control voltage generator is connected to the source of the adjustable voltage.