RU2742942C1 - Control method of power transmission line operation modes - Google Patents

Abstract

FIELD: electricity.SUBSTANCE: use in the field of electric power industry for control of operation modes of power transmission lines by means of transverse power compensation devices. Method of controlling operation modes of power transmission line is carried out by means of static power compensator, built on the basis of AC voltage regulator and reactive element, with connection of series connection of output clamps of AC voltage regulator and reactive element to one of phases of power transmission line. Method provides setting of power transmission line operation mode, synchronous measurement of currents and voltages of power transmission line, calculating current operating mode of power transmission line phase, calculating and generating control actions on static power compensator. At that, simultaneous control of operating modes in all phases of power transmission line is carried out by generating voltage on output terminals of AC voltage controller using linear voltage of other phases of power transmission line, and control action on static power compensator is calculated proceeding from current parameters of mode of all phases of power transmission line.EFFECT: broader functional capabilities of the static power compensator, which enables to generate in accordance with the specified requirements both reactive and active power in phases of the static power compensator and, accordingly, perform simultaneous more flexible control of power transmission line phases operation modes.1 cl, 3 dwg

Description

The invention relates to the field of electrical networks and can be used to control the operating modes of AC power lines (LEP) using transverse power compensation devices in order to reduce electrical energy losses, balancing the operating modes of the phases of power lines both in active and reactive power.

There is a known method for controlling reactive power in the phases of a power transmission line using a static power compensator, including setting and forming the required reactive resistance of a static power compensator for each of its phases, as well as synchronizing control actions to change the reactive resistance of the compensator with a sinusoidal network voltage (RU Patent for invention No. 2641643 published on January 19, 2018).

A known method of controlling the power of a static power compensator operating in a sinusoidal alternating voltage network and containing a series connection of a reactive element and a control device, including setting the power generated by the static compensator, measuring the voltage at the input terminals of the static power compensator, calculating the corresponding set generated power for each of the phases voltage of the control device, setting the impact on the control device, which ensures the formation of the calculated value of its voltage (Patent RU for invention No. 2675620 published on 21.12.2018). This method was chosen as a prototype.

The general disadvantage of the known methods (analogue and prototype) is that they allow to control only reactive powers in the phases of the power transmission line at the points of connection of the static power compensator to the phases of the power transmission line, while the implementation of control of active powers is impossible.

The technical task of the proposed method is to determine and form control actions on the static power compensator, providing, taking into account the parameters of the current mode of each phase, the implementation of the required operating modes of all phases of the transmission line.

The technical result of the claimed invention is to expand the functionality of the static power compensator, which makes it possible to form, in accordance with the specified requirements, both reactive and active powers in the phases of the static power compensator and, accordingly, to simultaneously carry out more flexible control of the operating modes of the transmission line phases.

The technical result is achieved by the fact that in the method of controlling the operating modes of the power transmission line, carried out by means of a static power compensator built on the basis of an AC voltage regulator and a reactive element, with the connection of a series connection of the output terminals of the AC voltage regulator and a reactive element to one of the phases of the power transmission line, using setting the operating mode of the power line, synchronously measuring the currents and voltages of the power line, calculating the current operating mode of the power line phase, calculating and generating control actions on the static power compensator, simultaneous control of the operating modes in all phases of the power line is carried out by forming the voltage at the output terminals of the AC regulator voltage using the line voltage of other phases of the power line, and the calculation of the control action on the static power compensator is carried out These are based on the current mode parameters of all phases of the power transmission line.

The essence of the invention is illustrated by drawings, where FIG. 1 shows a diagram of a device that implements the proposed method. FIG. 2 shows an example of the construction of a three-phase controlled device of transverse power compensation, implemented on the basis of a reactive power compensator, built using an alternating sinusoidal voltage regulator and a capacitor. FIG. 3 shows a vector diagram of voltages and currents in a reactive element, which explains the principle of operation of the device of FIG. 2.

FIG. 1 three-phase sinusoidal alternating voltage network is formed by sinusoidal alternating voltage sources 1, 2 and 3. Sinusoidal alternating voltage sources 1, 2, 3 are connected according to the "star" scheme with a common neutral point in node 4. The controlled transverse power compensation device 5 has phase inputs 6 , 7, 8 for connecting to the phases of the power line and input 9 for connecting to the neutral, while the phase inputs 6, 7, 8 of the controlled device of lateral compensation 5 are connected, respectively, to the nodes 10, 11 and 12. In this case, the node 10 is connected to the phase output sinusoidal alternating voltage source 1, node 11 is connected to the phase terminal of sinusoidal alternating voltage source 2, node 12 is connected to the phase terminal of sinusoidal alternating voltage source 3, and input 9 of the controlled lateral power compensation device 5 is connected to node 4. Three-phase load 13, 14 and 15, connected according to the "star" scheme, is connected, respectively, to the nodes 10, 11, 12 through current sensors 16, 17, 18. The common point of connection of loads 13, 14, 15 is connected to node 4 of sinusoidal alternating voltage sources 1, 2, 3. Voltage sensor 19 is connected between nodes 10 and 4, voltage sensor 20 is connected between nodes 11 and 4, the voltage sensor 21 is connected between nodes 12 and 4. The information outputs of the current sensors 16, 17, 18 and the information outputs of the voltage sensors 19, 20, 21 are connected to the inputs of the unit 22 for calculating the current operating mode of the power line phases, and the output of the unit 22 is connected to the first input of the control unit 23 controlled by the transverse power compensation device 5. The second input of the unit 23 is connected to the output of the unit 24 for setting the operating mode of the power transmission line. The output of the unit 23 is connected to the control input of the controlled transverse power compensation device 5.

FIG. 2 shows the simplest example of the implementation of the controlled lateral compensation device 5 and discloses its structure. The controlled transverse compensation device 5 is implemented on the basis of a reactive power compensator built using an alternating voltage regulator 25, the output terminals 26 and 27 of which are connected in series with the capacitor 28, forming a branch connected in parallel to the sinusoidal alternating voltage source 1 so that the output terminal 26 of the alternating voltage regulator voltage 25 is connected to the phase input 6 of the controlled transverse power compensation device 5, and the output terminal 27 of the AC sinusoidal voltage regulator 25 is connected to the first terminal of the capacitor 28, the second terminal of which is connected to the input 9 of the controlled transverse power compensation device 5. Input terminals of the AC voltage regulator 22 connected to phase inputs 7 and 8 of the controlled transverse power compensation device 5.

The claimed method is implemented as follows.

The controlled transverse power compensation device 5 in the circuit of FIG. 1 controls the modes of operation in the phases of the power line by using the principle of lateral compensation. The controlled device 5 is connected by its phase inputs 6, 7, 8 and 9 to the nodes of the power transmission line 9, 10, 11, 12 and 4, respectively. The signals from the current sensors 16, 17, 18 and voltage sensors 19, 20 and 21 are fed to the information inputs of the unit 22 for calculating the current operating mode of the power line phases, the task of which is to determine the operating modes of each of the power line phases. When a request for setting the required operating mode of the power transmission line is received from the block 24 for setting the operating mode of the power transmission line, the control unit 23 for the controlled transverse power compensation device 5 calculates the required control action on the controlled device for transverse power compensation 5, based on the parameters of the current mode of the power transmission line phases and adjusting characteristics of the controlled device for transverse power compensation 5, which determine the relationship of the powers generated by the controlled device for transverse power compensation 5 at the nodes of its connection to the phases of the power transmission line, with voltages at the phase inputs 6, 7, 8 of the controlled device for transverse power compensation 5.

It should be noted that in the known solutions, the control of the operating modes of the phases of the power transmission line is carried out by changing only the reactive power at the points of connection of the controlled device of transverse power compensation to the power line, since each phase of the controlled devices of transverse power compensation using known methods is represented as a passive reactive element, connected in parallel to each phase of the transmission line. Therefore, such controlled devices of lateral compensation, in essence, are reactive power compensators and can control the operating modes of the power transmission line phases independently of each other.

In those cases when the controlled device of the transverse power compensation 5 must also control the active power of the phase, this will require the organization of the exchange of active powers between the phases. It is obvious that a change in the operating mode in one phase will inextricably affect the operating modes of other phases. It should be noted that the control of the operating mode of the power transmission line implies setting the operating modes of all phases. In this case, the controlled transverse power compensation device 5 is represented as a device for simultaneously influencing the operating modes of all phases of the power line. The interrelation of the phase powers of the controlled transverse power compensation device 5 with the control actions generated by the block 23 sets its control characteristic. It is obvious that the control characteristic of the controlled device of transverse power compensation 5 will depend on its specific circuit design. Determination of the necessary control of the controlled device of transverse power compensation 5 to set the operating mode in each phase of the power transmission line should be based on information about the parameters of the current operating mode of the power transmission line, determined by block 22 based on the measured values of currents and voltages in the power transmission line at the points of connection of the controlled device to it transverse power compensation 5, the requirements for the new operating mode of the power line phases set by the unit 24, and the control characteristic of the controlled transverse power compensation device 5, which establishes the relationship of the powers generated by it in the power transmission line phases during their regulation.

FIG. 2 shows an example of the implementation of a controlled transverse power compensation device 5 based on an alternating voltage regulator 25 and a capacitor 28 used as a reactive element. The input terminals of the AC voltage regulator 25, connected to the phase inputs 7 and 8 of the controlled transverse power compensation device 5, are supplied with a line voltage generated by the AC sinusoidal voltage sources 2 and 3. The voltage at the output terminals 26 and 27 of the AC voltage regulator 25 (U _{26- 27} ) changes in proportion to the voltage at its input terminals. The voltage across the reactive element 28 (U _27-9 ) is determined by the vector sum of the voltage of the sinusoidal voltage source 1 (voltage U _10-9 ) and the voltage at the output terminals 26 and 27 of the AC voltage regulator 25 (voltage U _26-27 ). In the vector diagram of FIG. 3 shows these voltages, as well as the voltage across the capacitor 28 (voltage U _27-9 ). The current I ₂₈ in the capacitor 28 is ahead of the voltage U ₂₈ across the capacitor 28 by 90 electrical degrees. As seen in FIG. 3, the current in the capacitor 28 I _{28 is} ahead of the voltage of the sinusoidal voltage source 1 (voltage U _10-9 ) by an angle greater than 90 electrical degrees. This indicates the fact that in this mode the source of alternating sinusoidal voltage 1 consumes active power transmitted from alternating sinusoidal voltage sources 2 and 3. power compensation 5 simultaneously.

Thus, the use of a combination of features of the claimed invention allows for simultaneous control of the operating modes of all phases of the power line.

Claims (1)

A method for controlling the operating modes of a power transmission line, carried out by means of a static power compensator built on the basis of an AC voltage regulator and a reactive element, with connecting the serial connection of the output terminals of the AC voltage regulator and a reactive element to one of the phases of the power transmission line, using the setting of the operating mode of the power transmission line, synchronous measurement of currents and voltages of the power transmission line, calculation of the current operating mode of the phase of the power transmission line, calculation and formation of control actions on the static power compensator, characterized in that the simultaneous control of operating modes in all phases of the power transmission line is carried out by generating voltage at the output terminals of the AC voltage regulator using line voltage of other phases of the power line, and the calculation of the control action on the static power compensator is carried out based on the current x mode parameters of all phases of the power line.

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