RU2460198C1 - Power supply loss protection device - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device is composed of the following components: a unit of power direction control, a start-up unit of minimum frequency, the first, second and third logical AND units, the first, second and third timers, the first, second and third minimum voltage control units, a logical OR unit, the first and second actuating units. The first timer is an output of minimum frequency protection with control of power direction. The second logical OR unit and the second timer are an output of the first step of minimum voltage protection with control of power direction. The third timer is an output of the second step of minimum voltage protection. The first actuating unit acts at disconnection of a lead in a section of buses that lost power, and at suppression of a field of synchronous electric motors on a section of buses that lost power. The second actuating unit acts at disconnection of electric motors. The proposed device is designed for installation in cells of switchgears of transformer substations supplying to large synchronous electric motors.

EFFECT: higher resistance of process systems as a result of faster protection action and reduced idle time of process units.

2 dwg

Description

The invention relates to electrical engineering, in particular to a relay protection technique.

Known two-stage protection of the minimum voltage, comprising: starting blocks (voltage relay), time relay and output (intermediate) relay. The first stage with a time delay of the first stage acts either to turn off non-responsible electric motors, or to turn off the input of the busbar section of the switchgear that has lost power and to suppress the field of synchronous electric motors. The second stage acts to turn off the electric motors of the bus section that has lost power and then turn on the electric motors of the backup technological units and is designed to maintain the technological mode during a long interruption in power supply (Chernobrovov N.N., Semenov V.A. Relay protection of energy systems, 1998, p. 715, Fig. 19.12).

The disadvantage of this device is the limited performance in the presence of large synchronous motors at the substation. This drawback is caused by the fact that in the event of a loss of power due to remote short circuits in the supply network or in case of electrical communication with the source, the voltage on the bus section that has lost power can be maintained for a long time by synchronous motors that have switched to generator mode.

Closest to the proposed technical solution is a power loss protection device, which contains: a power direction control unit, a minimum frequency start-up block, a logic block, two minimum voltage control blocks, the first, second and third timers, the OR logic element, and two executive units ( Korogodsky V.I., Kuzhekov S.L., Paperno L.B. Relay protection of electric motors with voltage above 1 kV. - M.: Energoatomizdat, 1987, p. 188, Fig. 4.40).

The output of the first actuating unit is the output of the first stage of protection against power loss and acts to turn off the input switch of the busbar section of the switchgear that has lost power and to suppress the field of synchronous motors. The output of the second actuator unit is the output of the second stage of undervoltage protection and acts to turn off the electric motors.

The disadvantage of this device is the limited speed, which increases the downtime of technological units and can lead to significant technological damage to responsible consumers. Another disadvantage of the known device is the possibility of damage to the synchronous motor (DM) when restoring the voltage in the network after its short-term disappearance or deep reduction.

These disadvantages are due to the following. In the event of a power loss as a result of short circuits in the electrical network, a deep voltage drop occurs. Under conditions of reduced voltage, frequency relays may fail. In such modes, undervoltage control units are triggered. At the same time, the first undervoltage block acts to trip the input switch of the bus section that has lost power. However, such a shutdown occurs with a time delay, since in accordance with (Shabad MA Relay protection at power substations supplying synchronous electric motors. Electrician’s library, issue 565. - L .: Energoatomizdat, 1984, p. 56) time the operation of the timer in the circuit of the first undervoltage block must select a longer response time for those protections in the zone of operation of which damage can cause a decrease in voltage below those values at which the first undervoltage block operates.

The objective of the invention is to increase the speed of shutdown of the bus section, which has lost power. The second goal is to increase the safety of LEDs during voltage recovery after a short-term disappearance or a deep decrease.

The problem is solved in that the power loss protection device includes a power direction control unit, the inputs of which are connected to the input current of the busbar section of the switchgear and the voltage of the busbar section of the switchgear, the inputs of the three minimum voltage control units and the minimum frequency starting unit are also connected to the above voltage, the outputs of the control unit for the direction of power and the starting block of the minimum frequency are connected to the inputs of the first logical block And, which gives a signal to the first th timer, the outputs of the first undervoltage block and the power direction control unit are connected to the inputs of the second logical unit And, the outputs of the second undervoltage unit and the power direction control unit are connected to the inputs of the third logical unit And, which gives a signal to the second timer, and the logic element OR connected to the outputs of the first and second timers and the second logical block And, sends a signal to the first Executive block, the output of the third block of the minimum voltage is connected to the input t its timer to the output of which is connected a second execution unit.

The figure 1 presents a block diagram of the proposed device. The device contains: 1 - a unit for monitoring the direction of active power; 2 - the starting block of the minimum frequency; 3, 4 and 5 - the first, second and third blocks for monitoring the minimum voltage; respectively 6, 7 and 8 - logical blocks And; 9, 10 and 11 - timers with time delays t1, t2 and t3, respectively; 12 - logical element OR; 13, 14 - executive units.

The inputs of the power direction control unit 1 are connected to the voltage of the busbar section of the switchgear and the input current of the busbar section of the switchgear, the input of the minimum frequency unit 2 is connected to the voltage of the busbar section of the switchgear, the inputs of the first, second and third minimum voltage control units 3, 4 and 5 are connected to the voltage of the busbar section of the switchgear.

The device operates as follows.

In case of loss of power from an external source of power supply as a result of a violation of electrical communication with the source, synchronous motors go into generator mode. In this case, a decrease in the frequency and voltage on the bus sections begins and the direction of active power changes, which is controlled by the power direction control unit 1. When the frequency setting is reached, the starting block of minimum frequency 2 is triggered. Logic block 6, connected to the outputs of blocks 1 and 2, gives a signal to timer 9. The time t ₁ starts. With the passage of time t _{1, the} actuating unit 13 acts to turn off the input switch of the bus section and to suppress the field of synchronous motors.

In the event of a power loss due to short circuits in the electrical network, a deep voltage drop occurs. Under conditions of reduced voltage, frequency relays may fail. So the frequency relay type IVCh-3 fails at U <0.6U _nom , the relay type RF-1 - at U <0.2U _nom (A.V. Belyaev. Emergency control in load nodes with high-power synchronous motors. - M. : NTF Energoprogress, 2004, p.16). In such modes, undervoltage control units 3, 4 and 5 are triggered.

In the event that a short circuit occurred in the distribution network of the enterprise connected to the busbar section that lost power (at point K ₂ in figure 2), the direction of the active power does not change compared to the normal load mode, and the power direction control unit 1 does not work. Logic blocks 7 and 8 do not generate signals at their outputs, and the executive unit 13 does not work.

If a short circuit occurred in the external power supply network (at points K ₁ or K ₃ in figure 2), the direction of the active power changes, and the power direction control unit 1 activates. Short circuit location: on the supply line (at point K ₃ ) or on lines of the electric network that are not involved in the direct power supply of electric motors (at point K ₁ in figure 2), affects the value of the residual voltage on the bus sections to which electric motors that have lost power are connected.

If a short circuit occurred on the supply line (at point K ₃ in figure 2), the voltage on the busbar sections that lost power will be less than when a short circuit on the tires of the power supply IP1 at point K ₄ . In this case, all three undervoltage control units 3, 4 and 5 are triggered. When the first undervoltage control unit 3 and active power direction control unit 1 are triggered without delay, the executive unit 13 is activated, which acts to turn off the input switch Q2 of the bus section and to suppress field synchronous electric motors that have lost power (motor SD1 in figure 2). After the input switch is turned off, the automatic transfer switch (ATS) is activated, and the power of the electric motors that have lost power is restored by turning on the Q5 section switch.

Opening the Q2 opening switch without time delay during a short circuit on the supply line speeds up power recovery.

If a short circuit occurred on the lines of an external electric network that are not directly involved in powering the electric motors (at point K ₁ in Figure 2), the voltage on the tires to which the electric motors that have lost power are connected will be greater than when a short circuit on the source buses supply IP1 at point K ₄ . In this case, only the undervoltage control units 4 and 5 are triggered. When the second undervoltage control unit 4 and the active power direction control unit 1 are triggered, the logical unit 8 issues a signal to the timer 10. The time t ₂ starts. With the passage of time t _{2, the} actuating unit 13 acts to turn off the input switch Q2 of the bus section and to suppress the field of synchronous electric motors that have lost power (motor SD1 in figure 2). The time delay t ₂ is selected based on the following considerations. In the event of a short circuit in the mains, the protection of the damaged connection works, which opens the switch of this connection. However, it can be dangerous for diabetes. This is explained as follows. In the event of a short circuit at point K _1, protection A1 with a time delay of T4 opens the Q3 switch. During T4, the motors are in power loss mode. During T4, the SD1 motor brakes, and its EMF can change in phase with respect to the phase of the mains voltage by an angle close to 180 °. When the Q3 switch is turned off, the power is restored, while the EMF of the SD1 motor and the mains voltage may be in antiphase. This mode can lead to unacceptable currents in the stator winding SD1 and to the failure of the SD1 motor. The time during which the EMF phase of the SD1 engine can change by 180 ° is called critical. Denote it by T _KR . This time is 0.15-0.3 s. To ensure the safety of the LED engine when the short circuit is disconnected at point K _{1, the} time setting t ₂ must be less than the critical time T _КР . If the duration of the short circuit exceeds the critical, it is necessary to turn off the input switch Q2, followed by the start of the automatic transfer switch (ATS) and the inclusion of the section switch Q5.

In the event of an ABP device failure or Q5 circuit breaker failure, the third undervoltage control unit 5 with a time delay t _{3 of} timer 11 through actuation unit 14 acts to shut off the electric motors that have lost power (motor SD1 in figure 2).

In the known device there is no undervoltage control unit 3 and logic blocks 7 and 8. In this case, short circuits in the external electric network are disconnected with the same time delay, and in order to prevent the non-selective operation of the protection against power loss during short circuits in the distribution network, the response time is selected one step more than the time of those protection of the outgoing lines of the distribution network, in the area of which short circuits can cause the operation of the minimum voltage block shreds. This leads to an increase in the response time of protection from power loss up to 0.5-1.0 seconds or more, which increases the downtime of technological units and can lead to significant technological damage to responsible consumers.

In contrast to the prototype, the opening switch is disconnected during a short circuit on the supply line without delay, and the response time of the second timer t ₂ in the proposed device does not need to be selected one step higher than those protection of the outgoing lines of the distribution network, in the area of which short circuits can cause a trip undervoltage block. This leads to a decrease in the response time of protection against power loss, which reduces the downtime of technological units. In addition, reducing the response time below a critical value will increase the safety of LEDs when voltage is restored in the network after a short-term disappearance or a deep decrease.

Thus, in comparison with the prototype, the proposed device improves the speed of shutdown of the busbar section, which has lost power, which reduces the downtime of technological units and technological damage for responsible consumers and increases the safety of LEDs when voltage is restored in the network after a short-term disappearance or a deep decrease.

This invention improves the stability of technological systems and can find wide application in the technology of relay protection and automation.

Claims (1)

A power loss protection device including a power direction control unit, the inputs of which are connected to the input current of the busbar section of the switchgear and the voltage of the busbar section of the switchgear, the inputs of the three undervoltage control units and the minimum frequency start-up unit, the outputs of the directional control unit are also connected to the above voltage the power and the starting block of the minimum frequency are connected to the inputs of the first logical block And, which gives a signal to the first timer, the outputs of the the first undervoltage block and the power direction control unit are connected to the inputs of the second logical unit AND, the outputs of the second undervoltage unit and the power direction control unit are connected to the inputs of the third logical unit And, which gives a signal to the second timer, and the OR logic element is connected to the outputs the first and second timers and the second logical block And, sends a signal to the first actuator block, the output of the third block of the minimum voltage is connected to the input of the third timer, to the output which is connected to the second Executive unit.

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