RU123253U1 - POWER LOSS PROTECTION DEVICE FOR SUBSTATIONS WITH FREQUENCY-REGULATED SYNCHRONOUS ELECTRIC DRIVE - Google Patents

Abstract

Power loss protection device at substations with a frequency-controlled synchronous electric drive, including a power direction control unit, the inputs of which are connected to the input current of the switchgear busbar section and the voltage of the switchgear busbar section, the inputs of the minimum frequency starting unit and the control unit are also connected to the above voltage minimum voltage, the output of which is connected to the first timer, the outputs of the power direction control unit and the starting block of the minimum frequency are connected to the inputs of the first logical AND block, the output of which is connected to the inputs of the second and third timers and to the first input of the second logical AND block, the first executive block is connected to the output of the second timer, the logical OR block connected to the outputs of the first, third and fourth timers, sends a signal to the second executive unit, the pressure control unit in the pipeline at the outlet is connected to the second input of the second logical block AND, the output to is connected to the input of the fourth timer, characterized in that it additionally contains a differential pressure calculation unit, the inputs of which are connected to the outlet pressure control unit and the inlet pipeline pressure control unit, the output of which is connected to the input of the comparison unit, sends a signal to the third executive block.

Description

The utility model relates to electrical engineering, namely to the relay protection technique in substations with a frequency-controlled electric drive.

A device for protection against power loss is known, which contains: 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 minimum frequency trigger unit and the minimum voltage control unit, the output of which is also connected to the above voltage connected to the first timer, the output of the power direction control unit and the minimum frequency starting unit are connected to the inputs of the logic unit, which gives a signal to the second and third timers, the OR logical unit connected to the outputs of the first and third timers, sends a signal to the first executive unit, the second executive unit is connected to the output of the second timer. The output of the first output unit is the output of the minimum frequency protection against power loss with active power direction control 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 output unit is the output of two protections: protection of the minimum voltage and the second stage of protection of the minimum frequency and acts on the shutdown of synchronous motors that have lost power. / Patent for invention No. 2342755 "The device is protected against power loss. /

The disadvantage of this device is the lack of reliability when used in substations with frequency-controlled electric pumps for pumping liquid through pipelines.

Closest to the proposed technical solution is a power loss protection device, which contains: 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 minimum frequency starting block and the block are also connected to the above voltage control of the minimum voltage, the output of which is connected to the first timer, the outputs of the power direction control unit and the minimum start block the frequencies are connected to the inputs of the first logical block And, the output of which is connected to the inputs of the second and third timers and to the first input of the second logical block And, the logical block OR, connected to the outputs of the first, third and fourth timers, sends a signal to the first executive unit, the second executive the unit is connected to the output of the second timer, the pressure control unit in the pipeline, the output of which is connected to the second input of the second logical unit AND, the output of which is connected to the input of the fourth timer. The inputs of the power direction control unit 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 is connected to the voltage of the busbar section of the switchgear, the input of the minimum voltage control unit is connected to the voltage of the busbar section of the switchgear, the pressure control unit monitors the pressure at the reception of the pump unit, driven into rotation by an engine that has lost power. / Patent for invention No. 2421860 "The device is protected from power loss. /

The disadvantage of this device is the lack of reliability when used in substations with variable frequency synchronous electric pumps for pumping fluid through pipelines. In this case, loss of stability and violation of technological processes during power outages is possible. This disadvantage is due to the fact that, when using the known device in substations with a frequency-controlled electric drive, the action of protection against power loss does not depend on the position of the check valve in the pump harness. When using protection against power loss at substations of oil pumping stations, this can lead to a dangerous increase in pressure in the pipeline due to the formation of pressure waves, which in turn can lead to a rupture of the pipeline or shutdown by pressure of other pumping stations of the pipeline with a complete cessation of the pumping process.

The objective of the utility model is to increase the reliability of protection against power loss in order to maintain the stability of technological processes during power outages by introducing into the device circuit the function of controlling the motor braking process depending on the position of the check valve in the pump harness.

The problem is solved in that the power loss protection device in substations with a frequency-controlled synchronous electric drive, 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, also the inputs of the starting block are connected to the above voltage the minimum frequency and the minimum voltage control unit, the output of which is connected to the first timer, the outputs of the power direction and start control unit of the minimum frequency block are connected to the inputs of the first logical block AND, the output of which is connected to the inputs of the second and third timers and to the first input of the second logical block And, the first executive block is connected to the output of the second timer, the logical block OR, connected to the outputs of the first, third and the fourth timers, sends a signal to the second Executive unit, the pressure control unit in the pipeline at the output is connected to the second input of the second logical unit And, the output of which is connected to the input of the fourth timer, agrees but the utility model further comprises a differential pressure calculation unit, the inputs of which are connected to the pressure control unit in the pipeline at the outlet and the pressure control unit in the pipeline at the inlet, the output of which is connected to the input of the comparison unit, sends a signal to the third execution unit.

Figure 1 shows a device for protection against power loss in substations with a frequency-controlled synchronous electric drive; figure 2 - diagram of the frequency Converter through which the synchronous motor is connected to the mains; figure 3 is a diagram of the inclusion of a check valve in the piping of the pump, for the drive of which a protected synchronous motor is used.

The power loss protection device at substations with a frequency-controlled synchronous electric drive contains: power direction control unit 1, minimum frequency start-up unit 2, minimum voltage control unit 3, first timer 4, first logical unit I 5, second timer 6, third timer 7 , the second logical unit AND 8, the first executive unit 9, the logical unit OR 10, the fourth timer 11, the second executive unit 12, the unit 13 for monitoring the pressure in the pipeline at the outlet, the differential pressure calculation unit 14, the control unit 15 the pressure in the pipeline at the inlet, block 16 comparison, the third actuator block 17.

The frequency converter consists of a three-phase power rectifier 18, a three-phase autonomous inverter 19, a pulse-width modulation control system 20, a filter capacitor 21 in the DC link. An electric motor 22 with a pump 23 is connected to the output of the frequency converter. Braking resistance 24 and a key 25 are connected to the DC link for turning brake resistance 24 on / off. The inputs of the frequency converter are connected to the mains by voltage U.

The device operates as follows.

In case of loss of power from an external source of power supply, synchronous motors go into generator mode. In this case, a decrease in the rotational speed of the electric motor and the pump unit begins, as well as a decrease in the frequency and voltage on the tire sections, and the direction of the active power changes, which is controlled by block 1 in Fig. 1. The decrease in frequency on the tire section is controlled by block 2. The decrease in voltage on the tire section is controlled by block 3. When the pump unit speed decreases, the pressure at its intake increases, which is controlled by block 13.

When the frequency setting is reached, the minimum frequency block 2 is triggered. Logic block 5, connected to the outputs of blocks 1 and 2, gives a signal to timers 6 and 7. The countdown of t ₂ and t ₃ starts. With the passage of time t _2, the timer 6 is activated and the actuating unit 9 acts to turn off the input switch of the bus section and to suppress the field of synchronous motors. With a time delay of 13, timer 7 sends a signal to the executive unit 12 through the logic block OR 10, which acts to turn off synchronous electric motors that have lost power. Upon the fact of switching off synchronous electric motors, the automation circuit starts and turns on the electric motor of the reserve technological unit. The process is being restored.

In the case of successful extinction of the field of the synchronous electric motor, the voltage decreases on the bus sections, and the frequency control unit 2 or the power direction control unit 1 can return to the initial (unused) state and the timer 7 can return to its original state before the time t ₃ expires. In this case, due to a decrease in the voltage on the tires, the undervoltage monitoring unit 3 starts up and gives a signal to timer 4. A timer 4 with a time delay t ₁ sends a signal to the executive unit 12 through the logical unit OR 10, which acts to turn off the operating synchronous motors. Upon the fact of switching off synchronous electric motors, the automation circuit starts and turns on the electric motor of the reserve technological unit. The process is being restored.

If the pressure in the pipeline exceeds the maximum permissible value, the pressure monitoring unit 13 will operate and through the logic unit AND 8 will start the timer 11. The timer 11 with a time delay t ₄ through the logic unit OR 10 sends a signal to the executive unit 12, which acts to shut off lost power synchronous motors. Upon the fact of switching off synchronous electric motors, the automation circuit starts and turns on the electric motor of the reserve technological unit. The pressure in the pipeline decreases and the process is restored. The time delay t _{4 of} timer 11 is taken less than the time setting with which the maximum pressure protection of the pipeline acts to shut off the pumping station.

In substations with a frequency-controlled electric drive, when the power is lost in the circuit, the key 25 is turned on (Fig. 2) and the brake resistance 24 is connected to the frequency converter. This leads to fast braking of the motor 22 and the pump 23 connected to it. If the pump 23 is used for If oil is pumped through pipelines, then its accelerated braking leads to the formation of a steep front of the pressure wave in the pipeline. This increases the likelihood of triggering the protection by pressure and shutting down the main pumping unit by the maximum pressure. In addition, the steep front of the pressure wave, moving along the pipeline, is superimposed on the pressure available in the pipeline and can exceed the maximum allowable pressure on the mechanical strength of the pipeline. As a result, a rupture of the pipeline or a shutdown in pressure of other pumping stations of the pipeline with a complete cessation of the pumping process can occur.

In the proposed device, in contrast to the known one, there are blocks 14, 15, 16, 17. The input of block 13 is connected to a pressure sensor at the output of the main pump, and the input of block 15 is connected to a pressure sensor at the pump inlet. At the same time, at the output of block 14, a pressure difference is formed at the inlet and outlet of the pump, called the differential pressure. When the differential pressure is reduced to zero, a signal appears at the output of the comparison unit 16 and a signal is generated that is supplied to the third execution unit 17 to turn on the key 25 in the frequency converter circuit and the brake resistance 24 is turned on. That is, in the proposed device, the brake resistance 24 key 25 is not produced immediately after a power loss, but only after the differential pressure is reduced to zero.

This sequence of operation of the proposed device reduces the pressure wave in the pipeline and increases the reliability of protection against power loss. This is explained as follows.

In the main oil pipeline parallel to the main pump 23 between the inlet 26 and outlet 27 valves installed check valve 28 (Fig.3). In operating mode, the check valve 28 is closed by the differential pressure developed by the pump 23. When the power is lost, the motor 22 is braked and the differential pressure developed by the pump 23 is reduced. At a certain speed of rotation of the pump, the differential pressure decreases so that it cannot hold the check valve 28 in the closed position. The non-return valve opens. In the event of a power loss, a pressure wave is generated in the pipeline only when the check valve is closed. As soon as the non-return valve opens, all the liquid Q in the pipeline will go through the open non-return valve 28, bypassing the pump, and the pump ceases to influence the process of formation of the pressure wave. Therefore, before opening the check valve 28, it is undesirable to turn on the brake resistance 24. It is advisable to turn it on only after opening the check valve 28.

Thus, the use of the proposed device in substations with a frequency-controlled electric pump for pumping liquid reduces pressure waves in the pipeline, which increases the reliability of protection against power loss and ensures the stability of technological processes during power outages by controlling the braking process of a frequency-controlled electric motor depending on the position of the check valve in the pump harness.

Claims (1)

Device for protection against power loss at substations with a frequency-controlled synchronous electric drive, 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 minimum frequency start-up block and the control block are also connected to the above voltage minimum voltage, the output of which is connected to the first timer, the outputs of the power direction control unit and the start block the heats are connected to the inputs of the first logical block AND, the output of which is connected to the inputs of the second and third timers and to the first input of the second logical block And, the first executive block is connected to the output of the second timer, the logical block OR, connected to the outputs of the first, third and fourth timers, sends a signal to the second Executive unit, the pressure control unit in the pipeline at the output is connected to the second input of the second logical unit And, the output of which is connected to the input of the fourth timer, characterized in that it complements flax calculating unit comprises differential pressure, the inputs of which are connected to the unit control the pressure in the outlet conduit and the pressure monitoring unit in the pipe at the inlet, the output of which is connected to the input of the comparison unit provides a signal to the third execution unit.