CS269871B1 - Devices for measuring currents in high voltage networks - Google Patents

Abstract

) The device for measuring currents in high-voltage networks is intended for measuring transient and transient currents. The coupling between the high-voltage parts and the measuring circuits is made by optical fibers. The current in the conductor induces a magnetic field, which is measured by a Hall generator, the output voltage from the Hall generator is converted to a series form by an A/D converter and transferred to the decoder and indication circuits by an optical fiber. The power supply of the high-voltage network electronics is ensured by inductive coupling from the overcurrent. All circuits on the high-voltage side are inside a metal non-ferromagnetic housing, which protects them from the negative effects of electric current as well as from the effects of atmospheric discharges and transient overvoltage.

Description

The invention relates to a device for measuring currents in high voltage networks and allows measuring operating and transient currents in medium and high voltage networks.

The current state of the art uses current transformers for measuring currents in the network. The devices known so far, current transformers, require a design with perfect voltage insulation between the network and the output terminals intended for measurement. Current transformers are material-intensive, require regular inspection work and in the event of a fault they cause maximum short-circuit currents and endanger the safety of the operator.

The above disadvantages of the previous solution are eliminated by the solution, the essence of which is that two series are connected to the phase high-voltage conductor, consisting of a Hall generator, an operational amplifier, an A/D converter, an asynchronous serial data transfer circuit, an optical transmitter, an optical fiber, an optical receiver, a decoder and indication and memory circuits.

The advantage of the proposed invention is that the device allows measuring operating and transient currents in a high-voltage network without using a current transformer.

An example of the invention is illustrated in the drawings, where Fig. 1 shows a block diagram of a device for measuring currents in high voltage networks, and Fig. 2 shows a general wiring diagram of electronic elements for measuring currents in high voltage networks.

A metal, conductive, sealed, non-ferromagnetic housing 23 is attached to the phase high-voltage conductor 1 of the OOP. This housing surrounds the Hall generator 1, connected to the operational amplifier 2, which is further connected via the A/D converter 3 and the asynchronous serial data transmission circuit 12 to the optical transmitter 14, which is connected to the optical transmission receiver 18 by an optical fiber 16. Its output is connected to the decoder 20; The output of the decoder 20 is connected to the indication and memory circuits 22. The second Hall generator £ is also connected to the indication and memory circuits 22 via the second operational amplifier £, the second A/D converter £, the second circuit 17 of asynchronous serial data transmission, the second optical transmitter 15, the second optical fiber 17, the second optical receiver 19 and the second decoder 21. The supply coil 7 is connected to the supply regulator 8, which is further connected to the zero voltage terminal 100, the positive voltage terminal 101 and the negative voltage terminal 102. The measuring coil 26 is connected to a timing circuit 27, which is further connected to a second A/D converter 6. The voltage probe 9 is connected to a voltage-current converter 10 by an optical fiber 11, which is connected to an optical fiber 24 by an optocoupler 25, the output of which is connected to the indication and memory circuits 22. A permanent magnet 28 is attached to the Hall generator 1, a second permanent magnet 29 is attached to the first Hall generator 20. The function of the circuits shown in Fig. 1 is as follows. The operating or transient current flowing through the high-voltage conductor 1000 creates a magnetic field that passes through a metal conductively connected closed non-ferromagnetic junction box 23. Under the influence of this magnetic field, a voltage is induced in the supply coil 7, which is rectified, filtered and stabilized in the supply rectifier 8. The stabilized voltage is output to the terminals 101 and 102 and serves to power the electronic circuits. The magnetic field is formed by a phase high-voltage conductor 100. It also passes through the helium generators 1*4, at the output of which a voltage proportional to the size of the magnetic field arises. Since the measured current can contain a DC component, for reasons of separation of the positive * negative amplitude of the current, it is carried out by connecting the output terminals of the helium generators 1*4 to each other by means of an operational amplifier 2*5. The output voltage from the helium generator 1, proportional to the current in the phase high-voltage conductor 1 of the OOP, is amplified in the operational amplifier 2 and converted into digital form in the A/D converter J. The digital code is converted in the asynchronous serial data transmission circuit 12 into a form suitable for transmission by the optical transmitter 14 along the optical fiber 16 to the optical receiver 18. The optical fiber 16, the second optical fiber 17 and the third optical fiber 24 form an insulating member between the high-voltage circuits and the indication and panel circuits 22. The output signal from the optical receiver 18 is decoded in the decoder 20 and evaluated in the indication and memory circuits 22. from which it is possible to read the value of the measured current in the high-voltage network. .

The output voltage from the second Hall generator 4, which is equal to the negative amplitude of the current in the phase high-voltage conductor 1 PPP, is similarly processed in the second operational amplifier 2»

CS 269 871 Bl second A/D converter 6, second circuit 13 «synchronous data transmission and second optical transmitter 15. Second optical fiber 17 feeds data to second optical receiver 19 and through second decoder 21 to indication and memory circuits 22. Permanent magnet 28 and second permanent magnet 29 are used to compensate for the characteristics of Hall generators 1 and 4. Measuring coil 26 ensures registration of maximum current amplitude after switching on current to phase high-voltage conductor 1000 at a time when there is no voltage on power rectifier 8, timing circuit 27 ensures data transfer from measuring coil 26 to second A/D converter. The voltage probe 9 ▼ in cooperation with the voltage converter 10 - through the third optical transmitter 11, the third optical fiber 24 and the third optical receiver 25 transmits to the indication and memory circuits information about the presence of high voltage on the phase high-voltage conductor 1000. The metal, conductively connected, closed "ferromagnetic shielding case 23 shields the Hall generators 1,4. operational amplifiers 2, 5., the power supply coil 7, the measuring coil 26 and other circuits from the parasitic effects of the electric field and from other negative effects of high-voltage networks. The function of the circuit in Fig. 2 is as follows:

When the current circuit is switched on, a current begins to flow through the phase high-voltage conductor 1000, which generates a magnetic field. The magnetic field induces a voltage in the measuring coil 26, which, depending on the polarity, charges the input capacitor 82 via the input diode 81 and the second input capacitor 84 via the second input diode 83. At the same time, a voltage is induced in the supply coil 7, which is rectified via the first, second, third and fourth diodes 104, 105, 106 and 107 and charges the capacitor 108. The supply voltage then passes through the limiting resistor 109 to the filter capacitor 110 and to the Zener diode 111, which stabilizes the supply voltage. The dividing resistor 112 and the second dividing resistor 113 create a zero point of the supply voltage, which is output to the zero voltage terminals 100. The electronic circuits of the entire device are powered from the positive voltage terminal 101 and the negative voltage terminal 102. The capacity of the filter capacitor 110 ensures power supply to the device during a short-term interruption of the current in the high-voltage conductor 1 of the OOP. The supply voltage is applied via the resistor 128 of the Hall generator 1 to the positive supply terminal 203 of the Hall generator 1. At the positive input 202 and the negative output 204 of the Hall generator 1, there is a voltage proportional to the current in the phase high-voltage conductor 1000. which is applied via the negative input 401 and the positive input 407 to the operational amplifier 140. The operating conditions of the input parts of the operational amplifier 140 are set using the input divider resistor 129 and the second input divider resistor 130. The permanent magnet 28 and the potentiometer 133 and the divider resistors 129 and 130 at the input of the operational amplifier 140 set the mode of the operational amplifier 140 so that it operates at positive half-waves of the current in the phase conductor 1. OOP. Transistor 137 in cooperation with base resistor 135, emitter resistor 136 and collector resistor 134 ensures frequency compensation with compensation capacitor 138. The output voltage in the collector of transistor 137 is converted into digital form in monolithic A/D converter 141. The output of monolithic A/D converter 141 is connected to the input of asynchronous serial data transfer circuit 142. In this circuit 142, data is adjusted to a form suitable for transmission by optical transmitter 143. Optical fiber 144 ensures information transmission and at the same time galvanically separates high-voltage parts from inductive circuits. The transmitted data via the optical fiber 144 goes to the optical coupler 145. The obtained digital signal is adjusted in the decoder 146 and evaluated in the indication and memory circuits 22. The second Hall generator 4 has a second positive output 302 connected to a second negative input 507. The third input divider resistor 149, the fourth input divider resistor 150, the fifth input resistor 151, the sixth input divider 152, the second potentiometer 153 and the second permanent magnet 29 are set so that the second operational amplifier 160 operates at a negative half-wave of the current in the phase high-voltage conductor 1 OOP.

All other functions of this channel are completely identical to the channel corresponding to the operational amplifier 140. The voltage of the voltage probe 9 is fed via the rectifier voltage diode 171 and the protective resistor 172 to the protective Zener diode 173 and further via the limiting resistor 174 to the optical voltage transmitter 175. The data is fed through the optical fiber 176 to the optical receiver 177, from which information about the voltage state of the phase conductor, 0 - no voltage, 1 - high voltage, is transmitted to the indication and memory circuits 22. The delay circuit 88 ensures the transmission of information about the maximum current amplitude, which is stored in the input capacitor 82 and the second input capacitor 84. The transmission of this information is ensured by the gradual closing of the contacts of the timing relay 861 and the contacts of the second timing relay 862. The delay circuit 88 ensures the closing of the reset relay 85 and the disconnection of the timing relay 86 and the second timing relay 87 after reaching the nominal voltage at the positive voltage terminal 101 and the negative voltage generator 102. '

Kenotruktion conversion:

The device for measuring current in high-voltage lines enables the propagation of operating and transient currents at high-voltage and low-voltage levels. The device consists of electronic circuits inserted into a metal conductively connected closed non-ferromagnetic shielded housing 23. connected to the phase high-voltage conductor 1000. by a system of interconnecting optical fibers 16. 17, 24 and a system of optical receivers, decoders and indication! and memory circuits located at the ground potential of the station. The high-voltage part is designed for direct installation of the high-voltage line choke, which brings the advantage of a higher magnetic field intensity. The indication and memory circuits 22 indicate the current value on a digital display and enable further processing of the measured values in digital and analog form.

Equipping the substations of the high voltage and low voltage with this device will reduce the need for current transformers in the station. This simultaneously increases the reliability of the station operation. Another advantage is the simple installation of the described device into the network and the fact that the device shows high reliability, since even in the event of a single channel failure, the measurement remains preserved, with the exception of recording the DC component during transients. The optical coupling between the high voltage part and the indication circuits completely limits the transmission of parasitic voltages to the measuring and protective elements, which allows safe and reliable processing of the measured data by a computer.

Claims (3)

PÍBDMEIVYHLEZD , 1. A device for measuring currents in high-voltage networks, characterized in that a series consisting of a Hall generator (1), an operational amplifier (2), an A/D converter (3), a circuit (12) for asynchronous serial data transmission, an optical transmitter (14), an optical fiber (16), an optical receiver (18), a decoder (20) and indication and panel circuits (22) is soldered to the phase high-voltage conductor (1000), while a series consisting of a second operational amplifier (5), a second A/D converter (6), a second circuit (13) for asynchronous data transmission, a second optical transmitter (15), a second optical fiber (17), a second optical receiver (19), and a second decoder (21) is connected to the second Hall generator (4). 2. Device for measuring currents in high voltage wires according to item 1, characterized in that a series consisting of a maximum coil (26) and a timing circuit (27) is connected to the input of the second asynchronous data transmission circuit (13). 3. Device for measuring currents in high voltage networks according to item 1, characterized in that a voltage-current converter (10), a third optical transmitter (11), a third optical fiber (24) and a third optical receiver (25) are connected to the probe probe (9).