RU1836774C - Internal surge and ferroresonance process limiting arrangement for systems with compensated capacitive fault-to earth current - Google Patents

Abstract

Usage: high voltage technique. SUMMARY OF THE INVENTION: In the event of a resonant tuning mode of the arcing coil and, therefore, an insufficient current value for triggering the switching unit, the latter is triggered by the current signal received from the secondary circuits of the current transformer located in the dead-earth neutral of the high-voltage winding of the arcing apparatus connected to the supply section through the included three-phase disconnector. Thanks to the indicated current signal, the relay protection unit, the time relay and the switching unit are connected in series, which enables the connection of a three-phase low-voltage reactor to a low-voltage winding with a certain time delay, which excludes the switching apparatus from tripping during short-term and self-resetting single-phase short circuits. 1 ill. Ј

Description

The invention relates to high voltage electric networks with a voltage of 6-10 kV with compensated neutral mode. Capacitive single-phase earth fault currents are compensated by inductive currents of reactors located in the neutrals of the high-voltage windings of power transformers.

The purpose of the invention is the limitation of the parameters of internal overvoltages and ferroresonance processes to safe values for the isolation of electrical equipment based on complex compensation of capacitive currents of single-phase

earth faults and capacitive charge currents in intact phases.

This goal is achieved in that the device for limiting internal overvoltages and ferroresonance processes in networks with compensation of capacitive earth currents contains a power transformer, the high-voltage winding of which is connected to the star with an insulated neutral and connected to the supply section through the first switched on high-voltage three-phase switching device , and the low-voltage winding is connected according to a triangle circuit; arc coil connected by high voltage

x |

2

with

the house through the first closed single-phase disconnector to the neutral of the high-voltage winding of the power transformer, and with a zero output connected through the primary winding of the current transformer to the ground; an arcing unit, the high-voltage winding of which is connected to a star with a neutral, grounded through the primary winding of the current transformer, and is connected to the supply section through a closed three-phase disconnector, and the low-voltage winding is connected to an open triangle, to the terminals of which is connected through a second closed two-position disconnector, moreover, one of the conclusions of the low-voltage winding is grounded; a three-phase low-voltage reactor connected in a triangle circuit and connected to the linear terminals of the low-voltage winding of the power transformer through a second disconnected low-voltage three-phase switching device; a control circuit consisting of a secondary circuit of the first current transformer in the neutral terminal of the arcing coil, which is directly connected to the input circuits of the switching unit; a control circuit consisting of a secondary circuit of a second current transformer in a grounded neutral of high voltage and a voltage relay with a secondary circuit between the terminals of the open triangle of the low voltage windings of the arcing transformer, the secondary circuits being connected directly to the output of the relay protection unit, to the terminals of which are connected in series with the time relay and a unit for switching on a low-voltage three-phase switching apparatus.

Compared with the prototype, salient features are; limiting the parameters of the internal overvoltages of the ferroresonance processes to safe values for isolating electrical equipment based on the integrated compensation of capacitive currents of single-phase earth faults and capacitive charge currents in undamaged phases; complex interaction between relay protection devices and automation with ensuring the selectivity of their operation in functional dependence on emergency conditions in networks; the use of the resulting emergency and transient current t in the neutral of the high voltage windings and zero sequence voltage 3U0 in the open triangle of the secondary winding of the arc transformer, respectively, with the action of the control current 1H on the relay protection block, which in turn acts on the time-relay relays and the block

turning on the second low voltage three phase switching apparatus; the use of residual capacitive undercompensation current or inductive overcompensation current in total with the active component of the IOCT ground fault current. in the zero terminal of the arcing coil with the effect on the switching unit of the second low-voltage three-phase switching device directly; the use of a three-phase low-voltage reactor connected according to the triangle scheme and connected to the linear terminals of the low-voltage winding of the power transformer through a second disconnected low-voltage.

0 three-phase switching device.

Fixing the occurrence and limitation to safe values of internal overvoltages and ferroresonant processes in networks with compensation of capacitive 5 earth fault currents; complex compensation of small and large capacitive single-phase short-circuit currents to earth, eliminating damage to the insulation of electrical equipment from

0 electrical and thermal .. impacts go- responsibly; effectively reducing the likelihood of two-phase short circuits leading to emergency shutdowns of consumers of electrical energy.

The drawing shows an electrical diagram of the proposed device.

Power transformer 1 is connected by a three-phase high-voltage winding 2 through the first switching device 3 to the supply section 4. To neutral, 5 of the high-voltage winding is connected through the first arc disconnector 6, which extinguishes the coil 7, the zero output of which is grounded.

5 primary winding of the first transformer. current 8.

A three-phase low-voltage reactor 11 is connected to the low-voltage winding 9 of the power transformer through a second low-voltage three-phase switching device 10.

The arcing unit 12 is connected to the supply section of the high-voltage three-phase winding 13 through a three-phase disconnector5 holder 14. The neutral 15 of the high-voltage winding is deafly grounded through the primary winding of the second current transformer 16. The low-voltage winding 17 of the arcing reactor is connected via the second single-phase disconnector 18 to the low-voltage

reactor 19 and directly voltage relay 20.

The secondary circuits of the second current transformer in the high-voltage neutral and the voltage relay in the open triangle of the low-voltage winding arc are connected to the direct input of the relay protection unit 21, to the terminals of which are connected the time relay 22 and the switching unit 23, the second low-voltage three-phase switching device, and the secondary circuit the first current transformer 8 in the neutral earth terminal of the arcing coil is connected directly to the input circuits of the switching unit 23 about.

In the event of the occurrence of single-phase earth fault currents, especially small values of the order of 5 A, in cable networks with an insulated neutral, 5 overvoltages with alternating arcs reach values not less than: on the damaged phase — 1.7, on the undamaged phases — 3.1 1) f and neutral 5 high-voltage windings 2 power transformer 1-2.5 UV.

The values of the indicated overvoltages are practically preserved even in the presence of compensation of capacitive currents of shorting to ground with the help of an arcing coil 7 connected to the neutral 5 of the high-voltage winding 2 of the power transformer 1 using the first disconnector 6, when the power transformer 1 is connected using the first switching device 3 to the mains supply 4.

These overvoltages are the reason for the further development of the emergency mode with the emergence of a ferroresonance process due to the supersaturation of magnetic systems of voltage transformers like ZNOM and NTMI and other thermal damage to high-voltage windings with increased currents arising from a sharp decrease in their inductive resistance.

Similar ferroresonance processes also occur during non-phase conditions in networks with isolated or compensated neutral, which appear when the phases are broken as a result of burnout from the action of large currents of single-phase earth faults of the order of (20-30) A or more, i.e. . exceeding the minimum regulated values of directive materials. The reason for the appearance of increased voltages in this case, preceding ferroresonances, is also the resonant overvoltages resulting from the commensurability of the capacities remaining under

voltage of intact phases and phase inductance of the windings of power transformers.

The occurrence of 5 ferroresonance processes under out-of-phase conditions is also facilitated by the presence of capacitive charge currents in undamaged phases and areas of damaged phases remaining under voltage from the side of the supply transformer 10.

In the proposed protective device in the event of a single-phase earth fault, due to the presence of a residual compensation current - IOCT flowing through

5 winding of the arcing coil 7 and the primary winding of the first current transformer 8, in the secondary circuits of the latter there is a current signal that provides almost instantaneous operation of the unit

0 turn on 23 and turn on the second low-voltage three-phase switching device 10. providing in turn the connection of a three-phase low-voltage reactor 11 to the low-voltage terminals

5 windings 9 power transformer 1.

In the event of a resonant tuning mode of the arcing coil 7, and therefore, the IOCT current is insufficient for the switching unit to operate

0 23 the latter is triggered by the current signal n, received from the secondary circuits of the second current transformer 16, located in the dead earthed neutral 15 of the high voltage winding 13 of the arcing

5 of the apparatus 12, connected to the supply section 4 through the included three-phase disconnector 14.

Owing to the indicated current signal 1T, the relay protection unit 21, the time relay 22, and, respectively, the above-mentioned switching unit 23 are activated sequentially, which enables the connection of a three-phase low-voltage reactor 11 using a second switching device, 10 to a low-voltage winding 9 with a certain time delay, which excludes the operation of the second switching apparatus 10 for short-term and self-eliminating single-phase

0 shorting x, the so-called pecking at low currents shorting to the ground.

Thus, thanks to the complex interaction between these elements of the protective device in their

5 functional relationship from residual earth fault current and the resulting emergency current and transient processes 1n exclude the occurrence of ferroresonant and resonant phenomena

with hazardous electrical insulation. overvoltage and current parameters, i.e. the development of an emergency mode in a chain-cascade sequence with effectively limited overvoltages of alternating arcs of single-phase earth faults is excluded.

It is also important to note that under actual operating conditions of cable electric networks of industrial enterprises as a result of the occurrence of local defects in cable funnels or couplings with single-phase earth fault currents, non-phase modes arise in connection with the burnout of the phases on the fed feeders and, therefore, on the supply sections, which can lead to oscillatory processes with increased voltages acting on the entire network at corresponding lower or higher frequencies compared th with industrial frequency. The duration of exposure to increased voltages in the presence of local insulation defects and a cumulative effect leads to short circuits with the subsequent disconnection of the damaged area by the switching device and the appearance of undesirable switching processes.

Moreover, oscillatory processes can be maintained on the supply sections even after successfully disconnecting the damaged section of the network, which leads to the need for a short, but immediate and complete disconnection of the supply section and its subsequent switching on, which significantly complicates the maintenance the required selectivity of the existing typical relay protection for complex combinations of emergency conditions and transients acting simultaneously.

In the proposed protective device, with single-phase short circuits to the ground with the occurrence of out-of-phase modes, the voltage appears - 3Uo, the voltage relay 20 is activated, connected directly between the terminals of the low-voltage winding 17 of the arcing unit 12 in parallel with the low-voltage reactor 19 with the second 18-phase disconnector 18 V connected his chains. The control current arising in the control circuit after the operation of the voltage relay 20 leads to the operation of the series-connected relay protection unit 21, the time relay 22 and the switching unit 23 of the second switching device 10. +.

Compensation of capacitive charge currents with unbalanced and incomplete phase

modes using low-voltage reactor 11 reduces the overvoltage parameters to safe values for normal isolation of electrical equipment. With regard to weakened isolation, a deeper limitation of overvoltages is carried out by the combined state of the inductive load carried out by the low-voltage reactor 19 between the terminals of the low-voltage winding 17 of the arcing unit 12 depending on the frequency of the internal overvoltages in hertz.

Under the influence of internal overvoltages with a frequency below the industrial one, the inductive resistance value - XL of the low-voltage reactor 19 decreases. This automatically improves the efficiency of short-circuiting the terminals of the open triangle of the low-voltage coil 17, i.e. voltage reduction of the zero sequence is 3U0, and voltage relay 20 performs in this mode a backup action on

the case of subsequent possible occurrences of transients with increased frequencies.

Under the influence of internal overvoltages with frequencies exceeding the industrial frequency, the efficiency of limiting the zero-sequence voltage by the low-voltage reactor 19 decreases, but the operation of the voltage relay 20 increases, with the consequent positive technical factors indicated above.

Moreover, when all the same short-circuits are disconnected by feeder and, in many cases, single-phase switching devices, phase switching overvoltages and currents are very effectively reduced due to the shunt action of the high-voltage

three-phase winding 13 of the arcing unit 12, connected by linear leads to the phases of the supply section 4 using the disconnector 14, and the neutral directly to the ground, which excludes

the possibility of oscillation processes on the supply section after disconnecting the damaged part of the network, which is the source of the oscillation processes of the entire network.

5 The combined functional interactions between the two-phase low-voltage reactor 11 of the power transformer 1 and the high-voltage three-phase winding 13 of the arcing unit 12 based on the functioning of the proposed control circuits of the protective device eliminates the occurrence of dangerous overvoltage arising. when a phase shorted to ground is burnt while maintaining an alternating arc on it from the side of the power source on the one hand, and consequently, the neutral displacements of the network with their characteristic increases in not only phase, but also linear voltages to dangerous values; up to the phenomena of phase reversal, on the other hand .....,; G.

Thus, the integrated and functional interaction of the elements proposed. a protective device for realizing the technical possibilities of limiting internal overvoltages and ferroresonant processes in networks with compensation of capacitive short-circuit currents to the ground, the functional effects of currents IOCT-, IT., In. the operation of relay protection and automation of the entire electrical network provide a resultant and very significant economic effect.

In connection with the detailed and technically justified description based on the explanatory diagram of the cited information sources, it can be seen that the proposed device for protecting the insulation of electrical equipment in sections of 6-10 kV represents a technical solution to new problems carried out by previously unknown combinations mi means and ways mi.

Claims (1)

The claims reflect the technical solution of the above list of new tasks, which are disadvantages in the prototype and analogue. Moreover, the features of the distinctive part of the formula express a completely new cause-and-effect relationship compared to the prototype. The claims A device for limiting internal overvoltage and ferroresonance processes in networks with compensation of capacitive currents of ground fault containing a power transformer, the high-voltage winding of which is connected to the star with an isolated neutral and connected to the supply section through the first three-phase switching device, and the low-voltage winding connected according to a triangle circuit, an arc suppression coil connected between the neutral of the high-voltage winding of the power transformer and the ground through the first single-phase disconnector, from In that, in order to limit the internal overvoltages and ferroresonance processes to safe values for isolation, it is additionally equipped with three-phase reactors connected in the form of a triangle and connected to the terminals of the low-voltage winding of the power transformer via a second three-phase switching device, an arcing unit the high-voltage winding of which is connected to a star with a dead-grounded neutral and is connected to the network through a three-phase disconnector, the low-voltage winding is connected once a closed triangle with a step-controlled reactor connected to its terminals through a second single-phase disconnector, two current transformers, the first of which is connected to the earth circuit of the arcing coil, the second to the neutral of the high-voltage winding of the arcing unit, while the secondary circuits of the second current transformer and relay The voltages connected to the open triangle of the winding of the arcing unit are connected to the first input of the relay protection unit, the output of which through the time relay is connected to the VK unit li ne of the second phase of the switching device and the secondary circuit of the first current transformer is connected to a second input of block incorporation. ,