RU2629376C1 - Device protecting from single phase-to-ground fault of medium voltage distribution circuit - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: protection device contains matching current and zero- sequence voltage converters, band-pass frequency filters, a differentiator, a phase comparison circuit of two values, a zero-sequence voltage start-up unit, a short ground fault memory block that includes operative and long-term memory elements with two inputs - a recording one and an erasing one, the first time delay element, a short-time pulse generator on the front edge of the input signal, the first AND gate, an isolation breakdown meter, a control block of the dead-time pause duration, a zero-sequence current directional protection unit, the second and the third AND gates, the first and the second inhibition gates with one informational and two inhibiting inputs each, an OR gate, the second time delay element, four output relays. The output of the phase comparison circuit of two values is connected to the inputs of the time delay element, of the short-time pulse generator on the front edge of the input signal, of the control block of the dead-time pause duration, and to the informational input of the second inhibition gate. The recording input of the working storage element is connected to the output of the first time delay element. The erasing input is connected to the output of the short-time pulse generator on the front edge of the input signal. The output of the working storage element is connected to the first input of the first AND gate, which output is connected to the isolation breakdown meter and to the recording input of the long-term memory storage. The first output of the control block of the dead-time pause duration is connected to the first input of the second AND gate and to the first inhibiting inputs of the first and the second inhibition gates, and the second output is connected to the first input of the third AND gate and the second inhibiting inputs of the first and the second inhibition gates. The output of the zero-sequence voltage start-up unit is connected to the second inputs of the first, second and third AND gates. The inputs of the zero-sequence current directional protection unit are connected to the outputs of the matching current and zero-sequence voltage converters respectively, and the output is connected to the informational input of the inhibition gate. The output of the long-term memory storage is connected to the first output relay, the outputs of the second and the third AND gates are connected to the second and the third output relays respectively. The outputs of the first and the second inhibition gates are connected to the inputs of the OR gate which output is connected to the fourth output relay through the second time delay element.

EFFECT: increased selectability and stability of the operation of protection of medium voltage 6-35 kV of electric networks from single-phase-to-ground faults.

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Description

The invention relates to the field of electrical engineering and electric power industry and can be used for protection against single-phase earth faults (hereinafter referred to as OZZ) of cable and overhead lines of medium voltage distribution networks of 6-35 kV operating with isolated neutral or with resonant neutral grounding through an arcing reactor (with compensation capacitive currents).

In such networks, protection against OZZ, as a rule, acts on the signal in accordance with the requirements of the EMP, with the exception of the protection of lines supplying electric motors, and networks with increased requirements for electrical safety (mine, quarry networks, coal mine networks, peat mining, etc.). In medium voltage networks operating with insulated neutral, most of the OZZ (up to 90%) has an intermittent arc character. At a high frequency of repeated ignition and quenching of the grounding arc, the hazardous voltages are accompanied by hazardous overvoltages covering the entire electrically connected network, which can lead to secondary breakdowns of insulation and transitions of the hazardous voltages to double and multi-circuit earth faults or interfacial short circuits at the fault location, to increase the accident rate in the considered networks and reduce the reliability of power supply to consumers. Such dangerous arc OZZ, called intermittent arc OZZ (DPOZZ), in many cases must be turned off in order to protect the controlled network from overvoltage. The occurrence of the DPOZZ is also possible in compensated networks with large compensation disturbances (Khalilov F.Kh., Evdokunin GA, Polyakov BC et al. Protection of 6-35 kV networks against overvoltage / edited by F.Kh. Khalilov, G.A. Evdokunina, A.I. Tajibaeva .-- SPb .: Energoatomizdat, 2002. - 268 p.).

It is known that the elements of the medium voltage network inventory lowest dielectric strength have electric voltage of 6-10 kV, for which the value of the AC high voltage when testing should not exceed values U _isp = (2,8-2,9) U _f (Rules for Electrical Installations. 7th edition. Approved by order of the Ministry of Energy of the Russian Federation of 08.07.2002. No. 204). With this in mind, undoubtedly dangerous, primarily for cable networks of 6-10 kV, one should consider arc intermittent OZZ, accompanied by overvoltage multiplicities K _p = U _p.max / U _ft ≥ (2.8-2.9).

According to research (Shuin V.A., Shadrikova T.Yu., Dobryagina O.A. Ways of recognition of dangerous intermittent arcing faults to earth in 6-10 kV cable networks // Electricity through the eyes of youth. Scientific works of the VI International Youth Scientific and Technical conferences, November 9-13, 2015; Conference proceedings. T. 2. - Ivanovo: Ivanovo State Energy University named after V.I. Lenin. - 2015. - P. 213-218) in networks with isolated overvoltage neutral during repeated breakdowns of insulation exceed the specified level at intervals between repetitions bubbled insulation breakdown Δt ≤ ~ 70 ms. For larger than the indicated values of the time intervals Δt between repeated breakdowns of insulation, arc OZZs are not accompanied by overvoltages dangerous to the network and therefore do not require immediate disconnection of the damaged connection. This kind of OZZ is called arcing intermittent single-phase earth fault (DPRSZ).

An even smaller danger to the network is represented by short-term self-eliminating OZZ (“pecking the earth”, “instantaneous earth fault” - KROZZ). However, KROZZ, as a rule, precede all other varieties of OZZ - DPOZZ, DPROZZ and stable OZZ (SPD), and their selective fixation can be used to diagnose the isolation state of network elements. Existing versions of protection against earth faults do not have the ability to recognize arc-hazardous arc hazardous and non-hazardous to the network arc and cannot solve the problem of choosing the most effective protection action method (signal or shutdown) for this type of hazardous earth fault.

Known devices for overcurrent protection of the zero sequence (Further TZNP) (Fedoseyev AM Relay protection of electrical systems. - M .: Energia, 1976; Chernobrovoy N.V., Semenov V.A. Relay protection of energy systems. M: Energoatomizdat, 1998; Gelfand Ya.S. Relay Protection of Distribution Networks (Moscow: Energoatomizdat, 1987), based on monitoring the components of the industrial frequency of the zero-sequence current of the established OZZ mode, containing a measuring current connected to the zero-sequence current filter (hereinafter referred to as FTNP) and Aging to the RMS or RMS values of the controlled value. TZNP devices are most widely used in distribution electric networks with insulated neutral and with resistive earth grounding.

The disadvantage of this type of protection devices is the low efficiency of operation in arc OZZ (the possibility of excessive tripping during external failure of the operation due to internal damage), the scope of application is limited by the value of the own capacitive current of the protected connection, the inability to recognize arc OZZs that are dangerous and non-hazardous to the network and fix the KROZZ.

Known devices of directional current protection of zero sequence (hereinafter TNZNP) (Fedoseev AM Relay protection of electrical systems. - M .: Energia, 1976; Chernobrovoy NV, Semenov VA Relay protection of energy systems. M: Energoatomizdat, 1998 ; Gelfand Ya.S. Relay protection of distribution networks. M: Energoatomizdat, 1987), containing a power directional organ connected to a zero-sequence voltage filter (hereinafter FNNP) and FTNP, which controls the phase relations of the components of the industrial frequency of the summed values steady state OZZ. TNZNP devices have a wider field of application than TNZN, not limited by the value of the own capacitive current of the protected connection.

The disadvantage of protection devices of this type is not always sufficient selectivity and stability of operation in arc OZZ, inability to recognize dangerous and non-hazardous for a network of arc OZZ and fixation of KROZZ.

Known devices for directional impulse protection against OZZ (Popov I.N., Lachugin V.F., Sokolova G.V. Relay protection based on transient monitoring. - M., Energoatomizdat, 1986; Lachugin V.F. Directional impulse protection against earth faults // Energetik. 1997. No. 9. - P. 21; RU 2480882 C1, published on 04/27/2013; RU 2519277 C1, published on 06/10/2014; RU 2550348 C1, published on 05/10/2015, SU 1275622 A1, published 07.12.1986; Shuin V.A., Gusenkov A.V. Protection against earth faults in electric networks of 6-10 kV. - M.: NTF Energoprogress, Energetik. - 2001) based on the use of electrical transient quantities of the process during breakdown of the isolation of the phase of the controlled network to the ground, containing a pulse power direction unit connected to the low voltage and low voltage switch, reacting to the initial sign of the zero sequence power of the transient process (initial phase ratios of the transient current and voltage of the zero sequence) when the fault is triggered, voltage of the zero sequence of industrial frequency, for the detuning from switching switching in the network and other modes without OZZ, the element And, which serves to fix the joint the proper operation of these organs, logic elements, alarm elements, output protection relays.

In these devices for protection against OZZ, a zero-sequence voltage is used as a polarizing quantity, which creates the possibility of functional failures in case of violations of the initial phase relations of the compared values due to a network neutral offset.

The disadvantages of this type of protection devices are the lack of continuity of operation in the steady-state OZZ mode, which is necessary when searching for a damaged section of a line by the operational switching method in the network and when performing protection with a shutdown action, the inability to recognize dangerous and non-hazardous arc OZZs for the network due to the lack of continuity of the pulse body direction power in the time interval of the transition current of the OZZ.

A device for centralized impulse directional protection (SU 1275622 A1. Publ. 07.12.1986; Shuin VA, Gusenkov AV Protection against earth faults in electric networks 6-10 kV. - M .: NTF "Energoprogress", Energetik. - 2001), based on the use of phase relations of the transient voltage and transient currents of the zero sequence in the connections of the protected object at the initial moment of the OZZ, containing a starting element that responds to the voltage of the zero sequence, for detuning from transient modes not related to the OZZ; sign sensors of instantaneous values of the transient current to each of the n connections of the protected object, connected via current signal conditioners to FTNP; high-speed current starting element, the inputs of which are connected to the sensors of the sign of the instantaneous values of the transient current, and the output to the input of the unit for automatically changing the threshold of the current sensors; sensors of instantaneous values of the reference (polarizing) value, connected through the voltage signal conditioner to the low-voltage filter; schemes for comparing the initial signs of transient currents and the reference value, elements of RAM for storing the fact of coincidence of the initial signs of the compared quantities with the automatic erasing of any previously recorded information from them; elements of long-term memory, the transfer of information to which of the elements of RAM occurs when the trigger on the voltage zero sequence; executive elements (e.g. indicators) connected to the output of long-term memory elements.

In contrast to pulsed directional protections, it is not the zero sequence voltage that is used as the polarizing quantity, but its derivative, which ensures non-criticality of the protection to distortions of the initial phase relations between the transient voltage and zero sequence transient currents caused by the neutral displacement of the network in the mode preceding the SCR, for example, due to the asymmetry of the capacitances of the phases of the network to the ground, and during arc alternating or intermittent earth faults.

The disadvantages of the device (SU 1275622 A1. Publ. 12/07/1986; Shuin VA, Gusenkov AV Protection against earth faults in electric networks 6-10 kV. - M: NTF Energoprogress, Energetik. - 2001) are the lack of continuity of action in the steady-state OZZ mode, as well as the inability to recognize dangerous and non-dangerous arc network OZZs.

A device for directional impulse protection against OZZ (SU 675513 A1 publ. 07/25/1979), based on the use of electrical quantities of the transition process, containing a pulsed body direction power zero sequence with self-holding voltage zero sequence and automatic return when it disappears, one of the outputs of which connected to the measuring body of an alternating arc fault, triggered with a delay time depending on the number of breakdowns for the period the output of which is connected to the first input of the logical element I. The second output of the pulse element is connected to the second input of the logical element And, which generates a signal to disconnect the protected connection during arc intermittent OZZ, as well as with a fixation device for a stable circuit, the output of which is connected to the signaling element. The counter of the number of single breakdowns of insulation is connected to the third output of the pulse body of the direction of power of the zero sequence. This analogue provides for the possibility of fixing the KROZZ, actions on the signal with stable OZZ, as a rule, not representing a direct danger to the network, and on shutdown with arc OZZ.

The disadvantages of this device are the lack of continuity of the directional pulsed measuring body with stable SPS, the possibility of false alarms during transients, accompanied by the appearance of components of the zero sequence in modes without SPS, for example, when switching switching in the network, the impossibility of recognition using the proposed criterion based on control the number of breakdowns during the industrial frequency period, hazardous and non-hazardous to the network in terms of surge voltage tion of arc faults to earth.

The closest analogue to the proposed invention is a centralized device of an autonomous integrated directional protection against protective current protection (Shuin V.A., Gusenkov A.V. Protection against earth faults in electric networks of 6-10 kV. - M .: NTF "Energoprogress", " Energetik ". - 2001), containing matching transformers of current and voltage of zero sequence of transformer type; a differentiator connected to the output of the voltage converter; frequency filters that distinguish the working frequency band up to 3 kHz; schemes for comparing the time of coincidence with the time of mismatch between the signs of the current and the derivative of the voltage in the observation time interval (the time interval for the existence of the transient current) and the trigger, which responds to voltage of zero sequence of industrial frequency. The output of the comparison circuit and the output of the trigger for voltage are connected to the And logic element, at the output of which a signal appears about the occurrence of an SCR at the protected connection.

The closest analogue has a continuity of action over the entire time interval of the transient current, which increases the selectivity and stability of operation during arc OZZ, and in the steady state, the OZZ responds to phase relations of higher harmonics of the current and voltage of the zero sequence. Therefore, the device can be used to determine the damaged connection with both stable and arc OZZ.

The disadvantage of the prototype is the lack of a recognition function for varieties of earth faults, primarily dangerous and non-hazardous arc networks of the OZZ, as well as the lack of the ability to fix one-time self-eliminating insulation breakdowns.

The technical result, the achievement of which the present invention is directed, is to increase the selectivity and stability of functioning (technical perfection) of protecting medium-voltage electric networks of 6-35 kV from single-phase earth faults by recognizing all types of OZZ and choosing on this basis the most effective method of protection action - on signal or off.

The technical result is achieved by the fact that in the device for protection against single-phase earth faults of medium voltage distribution networks, containing matching current and voltage converters of zero sequence, band-pass frequency filters, a differentiator, a circuit for comparing phases of two quantities, a starting voltage organ of zero sequence, a short-term fixing unit is introduced earth faults, including elements of operational and long-term memory with two inputs - recording and erasing, the first time element ennoy delay generator short pulse on the rising edge of the input signal, a first AND gate and the counter number of insulation breakdown; a block for monitoring the duration of dead-time pauses was introduced; a block of current directional protection of the zero sequence; introduced the second and third elements AND, the first and second elements are FORBIDDEN with one information and two inhibitory inputs each; OR element entered; a second time delay element is introduced; four output relays are introduced, while the output of the phase comparison circuit of the two quantities is connected to the inputs of the time delay element, the short-term pulse shaper along the leading edge of the input signal, the dead time pause duration control unit and to the information input of the second BAN element, the recording input of the RAM element is connected to the output the first element of the time delay, and the erasing input is to the output of the short-term pulse shaper along the leading edge of the input signal, the output of the RAM element it is connected to the first input of the first AND element, the output of the number of isolation breakdowns connected to the counter input and to the recording input of the long-term memory element, the first output of the dead time pause duration control unit is connected to the first input of the second AND element and to the first inhibit inputs of the first and second elements BAN, and the second output is to the first input of the third AND element and to the second inhibitory inputs of the first and second elements is PROHIBITED, the output of the starting element of the zero sequence voltage is to the second inputs of the first oh, the second and third elements AND, the inputs of the block of current directional protection of the zero sequence are connected to the outputs of the matching converters of current and voltage of the zero sequence, respectively, and the output is to the information input of the element BAN, the output of the long-term memory element is connected to the first output relay, the outputs of the second and of the third AND element, respectively, to the second and third output relays, the outputs of the first and second elements are PROHIBITED - to the inputs of the OR element, the output of which is connected through the second element time delay to the fourth output relay.

Matching zero-sequence current and voltage converters, band-pass frequency filters, a differentiator, a phase comparison circuit of two quantities realize the function of a continuous measuring directional organ that responds to phase relations of higher harmonic components in a given operating frequency range in transient and, with sufficient sensitivity, in steady-state modes OZZ. The zero-sequence current directional protection unit introduced into the circuit of the protection device, responding to the phase relations of the current and voltage of the zero sequence of the industrial frequency, provides continuity of action for stable earth faults in networks with isolated neutral, in which, for small values of the total capacitive current, provide the required sensitivity of the directional protection based on higher harmonics with stable SPZ is not always possible. The introduced element of the time delay provides the detuning of the protection functions, intended for operation only with stable OZZ, from KROZZ.

The introduced block for fixing short-term earth faults, which includes elements of operational and long-term memory, the first element of the time delay of the signal, the driver of a short-term pulse along the leading edge of the input signal, the first element And, and the counter of the number of breakdowns of isolation ensures the fixing of KROZZ, as well as the first breakdowns of insulation that turn into DPROZZ, DPOZZ or UHOZZ. The short-term pulse shaper on the leading edge of the input signal and the first time delay element of the specified signal erase any previously recorded information from the RAM element before recording new information, which eliminates the possibility of false clamping when the network is switched, accompanied by surges in the transient current and voltage of zero sequence.

The introduced block for monitoring the duration of dead-time pauses, the logic implemented using the AND, BAN, OR, and output relays allow for separate fixing of DPRSZ, DPSR, UOZZ.

In FIG. 1 is a diagram of an earth fault protection device for medium voltage distribution networks. In FIG. 2 shows the dependence of the magnitude of the overvoltage ratio K _p on the time intervals between repeated breakdowns of insulation Δt for a network with an isolated neutral. In FIG. Figures 3 and 4 show the oscillograms illustrating the operation of the protection device during CroOZZ, DProZZ, DPOZZ and UOZZ in networks with isolated and resonantly grounded neutral, respectively, where the following notation is accepted:

1 - matching current converters;

2 - matching voltage converters;

3, 4 - bandpass frequency filters;

5 - differentiator;

6 is a diagram for comparing the phases of two quantities;

7 - starting voltage zero sequence;

8 - block fixation of short-circuit to ground;

9, 10 - elements of operational and long-term memory;

11 - the first element of the time delay;

12 - shaper short-term pulse along the leading edge of the input signal;

13 - the first element And;

14 - counter number of breakdowns of isolation;

15 - control unit for duration of dead time pauses;

16 - block current directional protection;

17 - the second element And;

18 - the third element And;

19 - the first element is FORBIDDEN;

20 - the second element is FORBIDDEN;

21 - element OR;

22 - the second element of the time delay;

23 - the first output relay;

24 - second output relay;

25 - third output relay;

26 - fourth output relay;

u ₁ ... u ₁₉ - signals at the outputs of blocks 1 ... 19, respectively.

The protection device against OZZ contains matching converters of current 1 and voltage 2 of the zero sequence, band-pass frequency filters 3 and 4, connected to the outputs of the converters 1 and 2, respectively, a differentiator 5 connected to the output of the band-pass frequency filter 4, a phase comparison circuit of two quantities 6, inputs which are connected to the output of the above-mentioned band-pass frequency filter 3 and the differentiator 5, the trigger element of the zero sequence voltage 7, connected to the output of the matching voltage converter sequence 2, characterized in that a block for fixing short-term earth faults 8 is introduced, including elements of operational 9 and long-term 10 memory with two inputs - recording and erasing, the first time delay element 11, the short-term pulse shaper along the leading edge of the input signal 12, the first element And 13 and the counter of the number of breakdowns of isolation 14; a block for monitoring the duration of dead time pauses 15, a block of current directional protection 16, the second 17 and third 18 elements AND, the first 19 and second 20 elements are BANNED with one information and two inhibit inputs each, element OR 21, the second element of the time delay 22, four output relays 23, 24, 25, 26, while the output of the phase comparison circuit 6 is connected to the input of the first time delay element 11, to the input of the short-term pulse shaper along the leading edge of the input signal 12, to the input of the control unit for the duration of dead time pauses 15, and to the information at the input of the second element, it is PROHIBITED 20, the recording input of the RAM element 9 is connected to the output of the first time delay element 11, and the erasing input is connected to the output of the short-term pulse shaper along the leading edge of the input signal 12, the output of the RAM element 9 is connected to the first input of the first AND element 13, the output connected to the input of the counter of the number of breakdowns of isolation 14 and to the recording input of the element of long-term memory 10; the first output of the control unit for the duration of dead-time pauses 15 is connected to the first input of the second element And 17 and to the first inhibit inputs of the first 19 and second 20 elements BAN, and the second output to the first input of the third element And 18 and to the second inhibit inputs of the first 19 and second 20 elements FORBID, the output of the starting element of the voltage of the zero sequence 7 to the second inputs of the first 13, second 17 and third 18 elements And, the inputs of the block of current directional protection of the zero sequence 16 are connected to the outputs of the matching transform current and voltage zero sequence 1 and 2, respectively, and the output is to the information input of the first element BANNED 19, the output of the long-term memory element 10 is connected to the first output relay 23, the output of the second 17 and third 18 And elements respectively to the second 24 and third 25 the output relay, the outputs of the first 19 and second 20 elements are PROHIBITED - to the inputs of the element OR 21, the output of which is connected through the second time delay element 22 to the fourth output relay 26.

The device operates as follows.

In the event of a breakdown of phase insulation to earth, the zero-sequence voltage 3u ₀ appears in the network, and zero-sequence currents 3i ₀ appear in the damaged and undamaged connections. From the primary zero-sequence current transducer (for example, FTNP) through the matching current transducer 1, a band-pass frequency filter 3, which isolate the higher harmonic components of the transient and steady-state fault currents in a given frequency range (usually from 150 Hz to 2000-3000 Hz), current 3i ₀ is supplied to the first input of the phase comparison circuit 6.

From the primary voltage converter of the zero sequence (for example, the voltage transformer of the zero sequence) through the matching voltage converter 2, a bandpass filter 4, identical to the bandpass filter 3 in the current channel 3i ₀ , the differentiator 5 voltage 3u ₀ is supplied to the second input of the phase comparison circuit 6.

At the same time, the zero-sequence current and voltage from the outputs of the matching converters 1 and 2 are supplied to the corresponding inputs of the block of current directional protection 16 from stable SCR, based on the control of the phase relations of the components of the operating current frequency and zero-sequence voltage. The block is used only in networks with isolated neutral.

The voltage of the zero sequence from the output of the matching Converter 2 is also supplied to the input of the starting body voltage 3u ₀ 7.

With a single self-eliminating breakdown of insulation, transient currents 3i ₀ in damaged and intact connections contain almost only rapidly decaying (within a few milliseconds) free components. In this case, transient current surges in damaged and undamaged connections in a given operating frequency range have the same shape, but opposite polarity. The derivative of the transient voltage 3u ₀ at the output of the differentiator 5 in the operating frequency range coincides in shape with the transient currents 3i ₀ , while the input voltage 3u _{0 is} phased so that the signals of the transient current of the zero sequence and the derivative of the transient voltage of the zero sequence at the inputs of the phase comparison circuit 6 for a damaged connection, they coincide in shape and sign, and for an undamaged connection, they coincide in shape but are opposite in sign. The indicated phasing of the higher harmonic components of the currents 3i ₀ and the derivative of the voltage 3u ₀ takes place in transient conditions for any kind of unstable GDZ at the protected connection, as well as with stable GDZ.

When the breakdown of insulation is internal (at the protected connection), a signal appears at the output of the phase comparison circuit 6, the duration of which is determined by the duration of the transient inrush current, along the front edge of which the shaper 12 generates a short-term pulse that erases any information previously recorded in the RAM element 9, and through a small the time delay specified by the first element of the time delay 11 is the recording of new information in the element of RAM 9. The transmission of information from the element of RAM 9 to e The element of long-term memory 10 is carried out through the first element And 13 only when the starting element is triggered by the voltage 3u ₀ 7, which ensures the detuning of the device for protection against switching interference and other modes not related to OZZ. The lifetime of the voltage 3u ₀ after the earthing arc is extinguished at the fault location is determined by the time of the additional charge draining from the capacities of the network phases, which, in networks with isolated neutral and in compensated networks, is usually hundreds of milliseconds. Therefore, the fixation of a short-term breakdown of insulation is ensured even at very short durations of inrush current transient (from fractions of a millisecond).

The counter 14 accumulates information on the number of breakdowns of isolation. The signal from the output of the long-term memory element 10 is supplied to the first output relay 23, which acts on a signal indicating the occurrence of an insulation breakdown (KROZZ) on the protected connection. Reset (acknowledgment) of the long-term memory element 10 is carried out manually by operational personnel by applying a signal to its erasing input. At the same time, the first output relay 23 returns to its initial state.

With a single breakdown of isolation, there are no signals at the outputs of the control unit for the duration of dead-time pauses 15. The signal that briefly arises in this case at the output of the second element BANS 20 is not supplied to the input of the output relay 26 due to the second time delay element 22. The block of current directional protection of the zero sequence 16 does not work due to the short-term isolation faults due to the short-term existence of the current signal 3i ₀ .

An alternating or intermittent arc OZZ is a sequence, in the general case non-periodic, of short-term self-eliminating breakdowns of insulation - ignitions and suppression of the grounding arc. With each breakdown of isolation, information is recorded in the element of long-term memory 10, counter 14, and the action on the output relay 23 occurs similarly to that described above. The contents of the counter 14 will increase by one at each repeated breakdown of isolation.

Block 15 controls the duration of time intervals Δt between pulses at the output of phase comparison circuit 6. Since the pulse duration at the output of block 6 is determined by the duration of the input current pulse 3i ₀ , this block indirectly controls the duration of current-free pauses between current pulses of the internal OZZ, on which the value depends overvoltages in the network accompanying the arc OZZ. In FIG. 2 shows the dependence of the overvoltage ratio K _p on the time intervals between repeated breakdowns of isolation Δt for a network with an isolated neutral.

In the case of DPSA, the time intervals Δt between repeated ignitions of the grounding arc satisfy the relation

where t ₁ = ~ 70 ms is the maximum time between repeated breakdowns of isolation, accompanied by overvoltages dangerous to the network (Fig. 2).

When condition (1) is fulfilled, the signal will appear at the first output of the control unit for the duration of current-free pauses 15.

In the case of DPSA, the time intervals Δt between repeated ignitions of the grounding arc satisfy the relation

where t ₂ is the time of complete draining of the additional charge from the capacitance of the network phases, i.e. the network returns to zero initial conditions before the repeated breakdown, depending on active losses in isolation and other network elements and usually having a value of the order of 150 ... 300 ms.

In case of overvoltage protection, as noted above, overvoltages during repeated breakdowns do not reach the values dangerous for the network (t. 1, Fig. 2), however, this type of SCR may be accompanied by a significant increase in the rms value of the current at the site of damage compared to the CVD, which is dangerous for some elements, for example, electric machines, in connection with which separate fixing of DPROZZ and UOZZ is necessary.

When condition (2) is fulfilled, the signal will appear at the second output of the control unit for the duration of current-free pauses 15.

When DPOZZ and DPrOZZ starting body voltage zero sequence 7 does not have time to return to its original state between repeated breakdowns of isolation and, as with SPD, is continuously in the tripped state.

In case of SPEC or DPSCH signal at the output 1 or 2 of the control unit for duration of dead time pauses 15, through the first 19 and second 20 elements the PROHIBITION are blocked the protection functions intended for operation with SPD - current directional protection of zero sequence based on the components of the industrial frequency (block 16) and current directional protection of the zero sequence on the basis of higher harmonics, which, with these types of SPZs, cannot function stably.

If the time intervals Δt between repeated ignitions of the grounding arc satisfy the relation

then, before each repeated breakdown, the starting element with a voltage of 3u ₀ 7 returns to its initial state. In this case, each repeated breakdown occurs at zero initial network conditions and is not accompanied by dangerous overvoltages and an increase in the rms value of the current at the site of damage. With this type of OZZ, the signal at the outputs of the control unit for the duration of dead-time pauses 15 is not formed, and the damage is recorded by the protection as KROZZ.

In the breakdown of isolation, which has turned into a stable OZZ, the recording of information in the element of long-term memory 10, the counter 14 will occur similarly to that described above with KROZZ. In this case, a signal appears at the output of the first relay 23, and the contents of the counter 14 will increase by one. In the stable OZZ mode with a sufficient level of higher harmonics in the zero sequence current, which is always provided in compensated networks, the signal at the output of the phase comparison circuit 6 and, therefore, at the input of the control unit for the duration of dead time pauses 15 is continuous, and the signals at the outputs of the block 15 are absent. Therefore, there will be no signals at the outputs of the second 24 and third 25 output relays, as well as signals at the inhibitory inputs of the first 19 and second 20 elements. With SPD in compensated networks, a continuous signal will appear at the output of the phase comparison circuit 6, the output signal of which through the second element is PROHIBITED 20, the OR element 21 and the second time delay element 22 are supplied to the input of the fourth output relay 26. In networks with isolated neutral with small total values capacitive current level of higher harmonics in the current 3i ₀ may be insufficient for stable switching phase comparison circuit 6. Therefore, in such networks directional protection algorithm discussed above on the basis of UOZZ higher ha monic is taken out of work manually by a cover plate at the second input of the OR 21 element, and a cover included at the first input of the specified OR 21 element is put into operation an algorithm of current directional protection of the zero sequence from SPD based on the components of the industrial frequency, implemented by block 16. When block 16 is activated its output signal is supplied through the first element BAN 19, the OR element 21 and the second time delay element 22 to the input of the fourth output relay 26.

The signal at the output of block 23 is similar to the signal at the output of block 10, at the output of block 17 is similar to the signal at the output of block 24, at the output of block 18 is similar to the signal at the output of block 25, at the output of block 22 is similar to the signal at the output of block 26.

Claims (1)

A protection device against a single-phase earth fault of medium voltage distribution networks containing matching current and voltage converters of zero sequence, bandpass filters, a differentiator, a phase comparison circuit of two quantities, a zero-sequence voltage trigger, characterized in that a block for fixing short-term ground faults is introduced including elements of operational and long-term memory with two inputs - recording and erasing, the first element of the time delay, forming Vatel short pulse on the rising edge of the input signal, a first AND gate and the counter number of insulation breakdown; a block for monitoring the duration of dead-time pauses was introduced; a block of current directional protection of the zero sequence; introduced the second and third elements AND, the first and second elements are FORBIDDEN with one information and two inhibitory inputs each; OR element entered; a second time delay element is introduced; four output relays are introduced, while the output of the phase comparison circuit of the two quantities is connected to the inputs of the time delay element, the short-term pulse shaper along the leading edge of the input signal, the dead time pause duration control unit and to the information input of the second BAN element, the recording input of the RAM element is connected to the output the first element of the time delay, and the erasing input is to the output of the short-term pulse shaper along the leading edge of the input signal, the output of the RAM element it is connected to the first input of the first AND element, the output of the number of isolation breakdowns connected to the counter input and to the recording input of the long-term memory element, the first output of the dead time pause duration control unit is connected to the first input of the second AND element and to the first inhibit inputs of the first and second elements BAN, and the second output is to the first input of the third AND element and to the second inhibitory inputs of the first and second elements is PROHIBITED, the output of the starting element of the zero sequence voltage is to the second inputs of the first oh, the second and third elements AND, the inputs of the zero directional overcurrent protection unit are connected to the outputs of the matching current and voltage converters of the zero sequence, respectively, and the output is connected to the information input of the FORBID element, the output of the long-term memory element is connected to the first output relay, the outputs of the second and third And elements respectively to the second and third output relays, the outputs of the first and second elements are PROHIBITED - to the inputs of the OR element, the output of which is connected through the second element time delay to the fourth output relay.

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