FR2705172A1 - Device for control of electrical apparatus such as a circuit breaker - Google Patents

Abstract

The present invention relates to a device for control of a first electrical apparatus equipped with a triggering device, arranged in series on a high-voltage or very high-voltage line with a second apparatus and intended to be operated rapidly when the voltage at the terminals of the second apparatus reaches a defined threshold. It comprises a resistive divider (20) mounted at the terminals of the second apparatus, a set of two Zener diodes (21) mounted in parallel on this divider (20) and connected to a set of two emitting diodes (22), two optical fibres (FO1, FO2) linked to the emissive diode assembly (22) and connected to a power electronics device (24) which is itself connected to the triggering device of the first apparatus.

Description

DEVICE FOR CONTROLLING AN ELECTRICAL APPARATUS SUCH AS A CIRCUIT BREAKER
The present invention relates to a device for controlling an electrical appliance such as a circuit breaker.

 More precisely, it relates to a device for controlling a first electrical device equipped with a tripping device, arranged in series on a medium, high or very high voltage line with a second device and intended to be operated quickly when the voltage across the terminals of the second device reaches a determined threshold.

 The object of the invention is to provide such a control device allowing automatic, rapid and safe operation of the first device.

 It applies in particular to the control of a circuit breaker connected in series to a current limiter on a medium, high or very high voltage line.

 In French patent application No. 92 13 746 filed on November 16, 1992 by the Applicant, a varistor and magnetic circuit current limiter is described.

The use of a varistor allows a branch of the magnetic circuit to be saturated very quickly in order to increase the inductance of the circuit. The varistor operates from a given value of the fault current and supports the passage of residual current until the circuit breaker opens. With such a limiter, to reduce the thermal stress on the varistor, it is necessary to cut off the residual or limited current by quickly opening the circuit breaker.

 The control device according to the invention is particularly applicable to this type of limiter.

 According to the invention, it comprises a resistive divider mounted on the terminals of the second device, a set of two Zener diodes mounted in parallel on this divider and connected to a set of two emissive diodes, two optical fibers connected to the set of diodes emissive and connected to an electronic power device itself connected to the trigger device of the first device.

 According to a preferred embodiment, the divider is made up of two resistors in series, called first resistance and second resistance, in parallel to the second resistance are connected the two Zener diodes, head to tail, and the first emissive diode, these three diodes being mounted in series, the second emissive diode is arranged head to tail in parallel to the first emissive diode and the two optical fibers are connected respectively to the first and second emissive diodes.

 Advantageously, the electronic power device comprises, under a stabilized power supply, two optical receivers to which the two optical fibers are respectively connected and whose outputs are processed to actuate a transistor controlling the trigger device of the first device.

According to a particular arrangement, said outputs work in negative logic and are connected to a door
NAND whose pulsed output is made continuous by a monostable and amplified by a set of inverters before being sent to said transistor.

 The invention is described below with reference to the figures which represent only a preferred embodiment.

 Figure 1 is a longitudinal sectional view of a current limiter associated with a circuit breaker and equipped with a control device according to the invention.

 Figure 2 is an electrical diagram of a control device according to the invention.

 Figure 3 is an electronic diagram of the power device of a control device according to the invention.

 FIG. 4 represent timing diagrams illustrating the operation of the control device according to the invention.

 The limiter shown in FIG. 1 is of the type described in French patent application No. 92 13 746. This current limiter inserted in series in a high voltage line LL 'comprises, per phase, in series with a circuit breaker 13 a first winding El of conductive material formed of two elementary windings El 'and E1 "wound in series and a second winding E2 of conductive material having a number of turns greater than that of the first winding El and mounted in parallel to the first winding El, the second winding E2 being in series with a varistor 16 and a resistor 19. These windings El 'and E1 "are wound so that their flux oppose creating a permanent inductive voltage drop of the order of 3% to 4% of the nominal phase-to-earth voltage of the line. The second winding E2 is wound so as to create a flux 2 adding to the fluxes 1 'and Elle in branch 9 of the magnetic circuit 2 during operation. varistor 16 in order to magnetize the air gap 11.

 The appearance of the fault results in an increase in the voltage across the limiter between points A and B or M and N, taking into account the increase in the values of the limiting inductance L (o and of the limited current Il This voltage depends on the value of the inductance limiting the inductance of the source and the type of fault.

 It is therefore necessary that the tripping of the circuit breaker 13 takes place when the voltage AB or MN exceeds a determined threshold.

 The control device will now be described.

 A resistive divider 20, of length determined by the maximum voltage appearing during the fault, is mounted at terminals A and B, this divider comprising two resistors in series R1 and R2, called first resistance R1 and second resistance R2. In parallel to the second resistor R2, two Zener diodes 21 are mounted which actuate two emitting diodes 22 each connected to an optical fiber 23. The optical signals are transmitted to an electronic power device 24 installed in the control cabin of the circuit breaker.

 The tripping order leaving this device 24 actuates the coil 25 of the circuit breaker 13 which opens with a mechanical opening time of the order of 10 milliseconds.

 It is thus possible to limit the passage of current through the varistor to a time of less than 20 milliseconds.

 As shown in FIG. 1, the resistive divider 20 is connected between the terminals A and B and is located in the dielectric cooling fluid 14 of the limiter. It can also be connected to the outside of the limiter, for example between terminals M and N. This is the case, for example, of a superconductive limiter using liquid helium as the dielectric cooling fluid. The divider 20 is then housed inside an insulating envelope provided with fins.

 The portion of optical fiber 26 in the fluid is under tension and leaves the enclosure 2 via a bushing 27.

The operation of the control device is as follows:
- under normal conditions, the inductive voltage drop with the nominal current is low on the order of a few hundredths of the phase-to-earth voltage; the current passing through the emitting diodes 22 is zero; the energy in Joules losses of the divider 20 is absorbed by the dielectric fluid of the limiter;
- in fault mode, the current increases very quickly; at 3In for example, In being the nominal current, the varistor operates under a voltage between A and B of 3
L0 o In Ç2,, L0 o being the permanent reactance of the limiter; this voltage makes it possible to automatically send an optical trip signal to the circuit breaker 13 via the optical fibers 23 and the electronic power device 24.

 The control device is described below in more detail using the electrical diagram in FIG. 2.

In parallel to the second resistor R2, at the terminals X and Y, two Zener diodes DZ1, DZ2, head to tail, and a first emissive diode T1 are connected in series, and a second emissive diode T2 is arranged head to tail in parallel to the first emissive diode T1,
Two optical fibers F01, F02 are respectively connected to the first and second emissive diodes T1,
T2 and connected to a power electronic device 24 itself connected to the triggering device of the first device.

Emitting diodes or optical transmitters T1 and
T2 can be HFBR 1602 from "Hewlett Packard" and are therefore inserted in series with the resistor R1 across the limiter using a so-called threshold circuit whose terminals are X and Y. They are supplied head to tail to be ready to react quickly whatever the polarity of the voltage at the precise moment of the limitation. The threshold circuit prevents, under normal conditions, the transmitters T1 and T2 from being subjected to any stress, however slight, to prevent any risk of untimely operation of the circuit breaker. On the other hand when the instantaneous voltage at the terminals of the limiter reaches the determined threshold, one of the transmitters is frankly excited and allows the rapid opening of the circuit breaker using the electronic power device 24 which will be described later and which is connected to this circuit by two optical fibers F01 and F02 which ensure the complete isolation of the control device of the medium voltage, high voltage or very high voltage line.

The second resistor R2 is chosen by calculation, as well as the voltage of the two Zener diodes DZ1 and DZ2, so that in permanent mode the permanent peak voltage across the terminals
AB is lower than that of these diodes so that the transmitters T1 and T2 are not traversed by any current, whereas in limiting mode as soon as the instantaneous voltage at the terminals AB exceeds the threshold value, the current is established in l '' one of the transmitters T1 or T2 depending on the polarity.

 The electronic power device 24 is described in FIG. 3.

 Under a stabilized 12 Volt power supply made from the auxiliary voltage thanks to a resistor R3, a Zéner DZ3 diode of 12 Volt and a decoupling capacitor C1, it includes two optical receivers RVl, RV2 to which the two optical fibers are connected respectively F01, F02. Depending on the polarity of the monitored voltage, one or other of the optical receivers RV1, RV2 is activated. These receivers can be HFBR 2602 from "Hewlett Packard". Their nonS1 and nonS2 outputs work in negative logic, i.e. they are at 1 in the absence of light and pass to O in the presence of light.

They are connected to a NAND G door which can be a
CD4011 of "RCA" and which makes it possible to make the logical OR operation of S1 and S2 by virtue of the Morgan rule Sl + S2 = no (nonSl * nonS2).

 Given the AC voltage at the terminals AB and the thresholds set for the light emission from the transmitters, the control output S3 is pulsed. It is made continuous by a monostable MS which can be a CD4047 of "RCA" and whose proper time is chosen to make the signal continuous.

 The nonQ output current is then amplified using a set I of inverters, for example six "RCA" CD4009, in parallel to allow rapid charging of the stray capacitance of the control electrode of a field effect transistor T, preferably of MOS technology and for example an "International Rectifier" IRLD540.

This transistor is voltage protected by a diode
Zener suitable DZ4 of minimum voltage greater than or equal to the maximum auxiliary voltage. It controls the trip coil 25 of the circuit breaker.

 This command can optionally be carried out via the auxiliary contact for computer-aided CAD control of the circuit breaker.

 The timing diagrams of FIG. 4 explain the operation of the electronic device 24.

In the absence of a short circuit in the line, the voltage at the terminals AB of the limiter is nominal, no light is emitted, nonS1 and nonS2 are at 1, the monostable
MS receives no pulse, transistor T is blocked and no current flows through coil 25.

 As soon as a short circuit appears, the limiter goes into action, develops an abrupt positive or negative transient voltage and very quickly and periodically requests one or other of the optical receivers RV1 and RV2 whose nonS1 and nonS2 outputs pass alternately from 1 to 0 and from 0 to 1 ,; at each transition from 0 to 1, the monostable MS maintains the output Q at 1 from the first transition observed, as long as the voltage exists.

 The transistor T then has its control electrode which suddenly goes to 1, very quickly goes into conduction and excites the trip coil 25.

 The circuit breaker is quickly activated and cuts the fault current previously limited by the limiter. From this instant, the current disappearing in the limiter, the voltage at the terminals AB is canceled and the transistor T cuts the coil 25. The control of the coil 25 is therefore automatic and the computer-assisted control only plays a safety role opposite the coil. This computer-assisted control is however necessary in the case where it is desired for operating reasons to be able to trip the circuit breaker manually.

 All measures are taken to avoid inadvertent control of the circuit breaker under the influence of electromagnetic disturbances.

For resistance to electromagnetic fields, the constituent elements of the control device are placed in a metal box 28 acting as a cage for
Faraday. Resistor R3 is preferably external to the box and can be mounted last by specifying its value. The electronic power device is protected against reverse polarity of the auxiliary voltage.

 The metal housing 28 is at potential 0 of the battery and must be isolated from ground. Otherwise it is possible to mount it in isolation in another case at ground potential.

High frequency filters L1, BP1 are available to withstand high frequency disturbances linked either to breaking or to circuit breaker switching operations.
L2, BP2 (figure 3) on the inputs a and b of the box.

 The zero of the control electronics is brought to the potential of the shielding box 28 to avoid any dV / dt variation between the components and this box.

 The optical fibers providing the control information guarantee that no common mode voltage is introduced from the threshold circuit of FIG. 2 at the medium, high or very high voltage potential.

 This threshold circuit is perfectly passive; a low-value shunt capacity C is mounted to avoid stressing the transmitters in differential mode if high-frequency voltages linked to operations requested the limiter or to eliminate the very fleeting transient voltage which may appear across the terminals of the limiter under voltage, given its low but not zero residual inductivity.

 The control device thus produced is very reliable, while comprising few components.

Claims (6)

 1) Control device for a first electrical device equipped with a tripping device, arranged in series on a medium, high or very high voltage line with a second device and intended to be operated quickly when the voltage across the terminals of the second device reaches a determined threshold, characterized in that it comprises a resistive divider (20) mounted across the terminals of the second device, a set of two Zener diodes (21) mounted in parallel on this divider (20) and connected to a set of two emitting diodes (22), two optical fibers (FOl, F02) connected to the set of emitting diodes (22) and connected to a power electronic device (24) itself connected to the triggering device of the first device.  2) Device according to claim 1, characterized in that the divider (20) consists of two resistors (R1, R2) in series, called first resistance (R1) and second resistance (R2), in that in parallel to the second resistor (R2) are connected the two Zener diodes (DZ1, DZ2), head to tail, and the first emissive diode (T1), these three diodes being connected in series, in that the second emissive diode (T2) is arranged head to tail in parallel to the first emissive diode (T1) and in that the two optical fibers (FOl, F02) are respectively connected to the first and second emissive diodes (T1, T2).  3) Device according to claim 1 or 2, characterized in that the electronic power device (24) comprises, under a stabilized supply, two optical receivers (RV1, RV2) to which the two optical fibers are connected respectively (Fol, F02) and whose outputs are processed to actuate a transistor (T) controlling the triggering device of the first device.  4) Device according to claim 3, characterized in that said outputs work in negative logic and are connected to a NAND gate (G) whose pulsed output is made continuous by a monostable (MS) and amplified by a set of inverters ( B) before being sent to said transistor (T)  5) Device according to one of claims, characterized in that the first device is a circuit breaker and the second device is a current limiter.  6) Device according to claim 5, characterized in that the tripping device of the circuit breaker is a coil.