RU123250U1 - HIGH VOLTAGE ELECTRIC TRANSMISSION WITH HIGH LEVEL OF CHARGE POWER COMPENSATION - Google Patents

Abstract

1. Electric transmission of extra-high voltage with a high level of compensation of charging power, containing the first and second substations with busbars, to which the power transmission line is connected through line switches with charging power compensation devices connected through high-voltage switches, as well as automation, control and relay protection devices installed at each substation, characterized in that it additionally contains two automatic switching control units, the input of the first unit is connected to the input of the linear switch actuator connected to the busbars of the first substation, and the output is connected to the actuator of the high-voltage switch installed in the charging power compensation device circuit from the side of the first substation, the input of the second switching control automation unit is connected to the executive body of the line switch connected to the busbars of the second substation, and the output is through a delay device with the performer a high-voltage switch installed in the circuit of the charging power compensation device from the side of the second substation. 2. Electric transmission of ultra-high voltage with a high level of compensation of charging power according to claim 1, characterized in that a shunt reactor is used as a charging power compensation device. Ultra-high voltage power transmission with a high level of compensation of charging power according to claim 1, characterized in that a controlled shunt reactor is used as a charging power compensation device installed at the first substation, and as

Description

The proposed technical solution relates to the field of electrical engineering and can be used in power transmission of high and ultra-high voltage.

Electric power transmission systems are known in which, in order to increase the reliability of equipment operation and reduce switching overvoltages, an additional logic circuit breaker control unit for linear switches containing a delay unit is introduced into the automation device [Copyright certificate No. 1101948].

The disadvantage of this technical solution is the low efficiency when used in power transmission with a high degree of compensation of the charging power, since in case of non-phase outages of the power line there is a dangerous increase in voltage.

Closest to the proposed technical solution is the power transmission, in which automation devices monitor the state of the circuit breakers in the shunt reactor circuit and disconnect them from the power line with a time delay [Copyright certificate No. 1051644].

The disadvantage of this technical solution is the high aperiodic and low level of the periodic component of the current in the linear circuit breakers during power line switching with a high degree of compensation of capacitive current and, as a consequence, the possibility of failure of the circuit breaker when disconnecting asymmetrical short circuit

The purpose of the proposed technical solution is:

- preventing the development of resonant overvoltages in the undamaged phase with the possible failure of the linear switch

- a decrease in the level of the aperiodic component, an increase in the magnitude of the periodic component of the line current and, as a result, an increase in the reliability of the circuit breakers in the power line circuit.

This goal is achieved by the fact that an extra-high voltage power transmission with a high level of charging power compensation, containing the first and second substations with busbars, to which a power line is connected via line switches with charging power compensation devices connected through high-voltage switches, as well as automation, control and relay protection installed at each substation, additionally contains two blocks of automation control switching, the input of the first block with dinene with the input of the executive body of the linear switch connected to the busbars of the first substation, and the output with the executive body of the high-voltage switch installed in the circuit of the charging power compensation device from the side of the first substation, the input of the second block of automation control switching connected to the executive body of the linear switch connected to the busbars of the second substation, and the output through the delay device with the executive body of the high-voltage switch installed in pi charging power compensation device from the second substation, and as the charging power compensation device uses a shunt reactor; in this case, as a charging power compensation device installed at the first substation, to which power lines with charging power compensation devices connected via high-voltage switches are connected via linear switches, a controlled shunt reactor is used, and as a charging power compensation device installed on the second substation, to which power lines with devices connected via high-voltage switches are connected via linear switches Charge power compensation uses a shunt reactor; in addition, a shunt reactor is used as a charging power compensation device installed in the first substation, to which power lines with charging power compensation devices connected via high-voltage switches are connected, and a charging power compensation device installed in the second substation is used, to which power lines are connected via line switches with compensation devices connected via high-voltage switches and charging power, a controlled shunt reactor is used; wherein the delay time of the signal carried out by the delay device is selected from the condition t _off.s.c <t _s <t,

where t _s - the duration of the delay,

t _off ^{_ the} duration of disconnection of a short circuit by linear switches,

t is the duration of the allowable effect of voltage increases on high-voltage equipment;

in addition, the delay time of the signal carried out by the delay device is selected from the condition

t _UROV <t _s <t,

where t _s - the duration of the delay,

t _UROV - the duration of the backup devices failure breakers

t is the duration of the allowable effect of voltage increases on high-voltage equipment.

Fig. 1 shows an ultra-high voltage power transmission with a high level of charging power compensation, containing substations with busbars 1, 2 to which a power line 5 is connected through line switches 3, 4. A power compensation device 7 is connected to power line 5 through a high-voltage switch 6 and through a high-voltage switch 8 - a device for compensating charging power 9, as well as automation, control and relay protection 10, the output of which is connected to the executive body switches 3, 4, as well as with the input of the first block of automation control switching 11, the output of which is connected to the input of the actuator of the high voltage switch 6, and the input of the second block of automation automation of the switching 12, the output of which through the delay unit 13 is connected to the input of the actuator of the high voltage switch 8.

Power transmission works as follows. In the normally established mode, the power line 5 operates with normally switched linear switches 3 and 4 and high-voltage switches 6 and 8.

If an asymmetric short circuit occurs on the power line by 5 actions of the automation, control and relay protection device 10, the linear switches 3 and 4 are turned off, at the same time sending a command to turn off the high voltage switch 6 in the circuit of the shunt reactor 7 and to turn off the high voltage switch 8 in the circuit of the shunt reactor 9 through delay unit 13.

Blocks of automation control switching 11, 12, depending on the nature of switching - turning on or off the linear switch 3, 4, - form a command to turn on or off the high voltage switches 6, 8.

Thus, with the possible failure of the linear switch 3 or 4 of the damaged phase of the power line 5, the development of resonant overvoltages in the undamaged phase is prevented. Upon successful shutdown of the power line 5, the automation, control and relay protection devices 10 give a command to re-enable the power line 5 by the line switch 4. At the same time, a command is issued to turn on the high-voltage switch 6 in the circuit of the shunt reactor 7, which will reduce the aperiodic component of the current to values equal to periodic component, and in case of unsuccessful automatic restart, that is, switching on to an unresolved short circuit, disconnect the power line feeders 5. In this case, the periodic and aperiodic components of the current will flow through the linear switch 4 in uninterrupted phases, and the magnitude of the aperiodic component of the current at the moment of divergence of the switch contacts will be less than the amplitude values of the periodic component.

In the case of a successful automatic restart with a time delay sufficient to open the circuit breaker during an unsuccessful automatic restart, a command is issued to turn on the high voltage switch 8 of the shunt reactor 9, which reduces the voltage on the power line 5, and then the line switch 3 is turned on.

In case the shutdown of one of the shunt reactors does not reduce the degree of compensation of the charging power of the line below 50% of the installed charging power, a controlled shunt reactor should be installed. In this case, the logic of operation of the shields remains the same, only the power of the controlled shunt reactor should be selected so that the power consumed by the controlled shunt reactor is approximately 45% of the charging power of the power line.

Claims (6)

1. Power transmission of extra-high voltage with a high level of compensation of charging power, containing the first and second substations with busbars, to which through a linear switch connected to a power line with connected through high-voltage switches, devices for compensating charging power, as well as automation, control and relay protection installed at each substation, characterized in that it additionally contains two blocks of automation control switching, the input of the first block is connected to the input ohm of the executive body of the linear switch connected to the busbars of the first substation, and the output is with the executive body of the high-voltage switch installed in the circuit of the charging power compensation device from the side of the first substation, the input of the second switching automation unit is connected to the executive body of the linear switch connected to the teams to the buses of the second substation, and the output through the delay device with the executive body of the high-voltage switch installed in the device circuit and compensation of the charging power from the second substation. 2. Power transmission of ultra-high voltage with a high level of compensation of the charging power according to claim 1, characterized in that a shunt reactor is used as the device for compensating the charging power. 3. Ultra-high voltage power transmission with a high level of charging power compensation according to claim 1, characterized in that a controlled shunt reactor is used as a charging power compensation device installed in the first substation, and a charging power installed in the second substation as a charging power compensation device a shunt reactor is used. 4. Ultra-high voltage power transmission with a high level of charging power compensation according to claim 1, characterized in that a shunt reactor is used as a charging power compensation device installed in the first substation, and used as a charging power compensation device installed in the second substation controlled shunt reactor. 5. The ultra-high voltage power transmission with a high level of compensation of the charging power according to claim 1, characterized in that the delay time carried out by the delay device is selected from the condition t _off. <t _s <t, where t _s - the duration of the delay, t _off - the duration of disconnection of a short circuit by linear switches, t is the duration of the allowable effect of voltage increases on high-voltage equipment. 6. Power transmission of extra-high voltage with a high level of compensation of charging power according to claims 1 and 5, characterized in that the delay time carried out by the delay device is selected from the condition t _UROV <t _s <t, where t _s is the delay time, t _UROV - the duration of the operation of the device failover redundancy switches t is the duration of the allowable effect of voltage increases on high-voltage equipment.