RU2473999C1 - Method to increase efficiency of shunting reactor controlled by magnetisation - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: in a controlled shunted reactor there are additional resistive resistances used in semi-neutrals of a network winding. A converter-inverter is connected via a transformer to a distribution device of a substation grid with increased output voltage at the DC side. Functions of control are distributed by converting units connected directly to a reactor and to a distribution device of a substation grid.

EFFECT: improved dynamic characteristics, prevention of a voltage avalanche effect, occurrence of overvoltages in an AC grid and reduced multiple effects at equipment insulation.

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Description

The invention relates to electrical engineering, in particular to reactive power control devices, and can be used in magnetization-controlled shunt reactors of 35-220 kV to provide improved control characteristics of the mains current and power. The technical result is an increase in the speed of a shunt reactor controlled by magnetization (time to set and reset power).

The known reactor "Electric magnetization controlled three-phase reactor" (1), containing the actual reactor, which consists of three closed single-phase rod magnetic circuits, each of which has two rods, as well as a two-section network winding (CO) and a two-section control winding (OS), when In this section, the CO sections located on each rod are connected in parallel and connected to a three-phase network, and the three OS sections located on the same rods of three magnetic cores are connected in series into an open triangle, in while the other three sections of the op-amp of the other cores of the magnetic circuits are connected in series into a second open triangle, while two open triangles are connected in parallel and connected to an adjustable bias DC source. A semiconductor converter unit is used as an adjustable DC bias source. In addition, there is an automatic control system that, according to a given control law, changes the opening angle of the thyristors, thereby changing the rectified bias current, and, accordingly, the current and power consumption of the reactor.

The device described in the USSR copyright certificate is also known (2).

In device (1), which is the closest analogue, optimization of technical and economic indicators is carried out in comparison with the device described in analogue (2), the number of winding sections is reduced, which caused increased costs in production and additional consumption of materials, but it did not It is envisaged to improve the characteristics of reactive power regulation by increasing speed.

Moreover, in some cases, the control parameters possessed by the device (1) are optimal for reliable operation of the power system and are also economically feasible, however, there is often a need for increased reactor speed, for example, for use in a “weak” network with a significant proportion of engines load, in networks with the presence of consumers, which are sensitive to a significant change in voltage, as well as to the speed of its change.

Slow performance is a disadvantage of the known device (1) and can lead to overvoltages in the AC network to which the reactor is connected, excessive disconnection of consumers sensitive to voltage levels, “voltage avalanche”, which is an unacceptable circumstance.

The low speed is associated with the design feature of the reactor, converter units, the presence of direct electromagnetic links between the windings, which leads to the appearance of equalized rectified currents in CO in transient conditions, which prevent a rapid change in current in the CO of a controlled shunt reactor (CSR), and, accordingly, a change in power the reactor.

In device (1), it is proposed to connect a bias system to a switchgear (RU) of 6-35 kV substation, which leads to a decrease in its functionality. In addition, the power of the bias system used is insufficient to provide a more rapid change in the state of the magnetic field-contact system.

In accordance with a real waveform, a power gain of 5% -100% In of a controlled reactor of 25 MB · Ap 110 kV (1) is carried out in a time equal to 3.2 sec, at a network voltage of 110 kV. The current flowing through the converter unit reaches its rated mode in 0.35 seconds and does not increase any more, which means the current limit of the converter, calculated for a current of 110% In. From the foregoing, we can conclude that the transient process and the nature of the increase in current in the control winding (OS) and the network winding (CO) do not correspond to each other, which is explained by the protracted processes of long attenuation of the DC component in the CO.

In accordance with the transient waveform (the following parameters are given: the current of one phase of the network winding, the induction in the reactor rod, the currents of two half-neutrals of the network winding, the voltage of the network 110 kV) with a change in the CSR power of 5% -100% according to the mathematical model using the network resistive windings of 10 Ohms, the output voltage of the converter unit increases four times in comparison with the analogue (1). The proposed measures allow to reduce the time to gain power of the CSR 5% -100% In from 3.2 seconds to 0.35-0.3 seconds, which is a significant increase in the dynamic characteristics of the equipment.

The application of these measures - the installation of resistive resistance in the half-neutral of CO and an increase in the power of the transformer-converter unit, allows not only to significantly reduce the power-up time of 5% -100%, but also significantly reduce the power-off time of 100% -5%. In addition to the listed improvements, it is necessary to provide an invert mode.

In accordance with a real waveform of a power drop of 100% -28% of analogue (1) (the following parameters are given: voltage of the network 110 kV, currents of the network winding of the reactor, current through the converter block of the reactor), the reactor current decreases in 3.75 seconds. In analogue (1), the converter unit does not work in the inverter mode, which significantly degrades the technical characteristics of the CSR.

There is also a real waveform of the transitional mode when changing the power of the CSR 100% -5% In according to the mathematical model using 10-ohm resistive resistances in half-neutrals of the network winding, quadrupled as compared with analogue (1) with the output voltage of the converter unit, while for accelerated Power Reset CSR The converter unit operates in invert mode. The following parameters are given: current of one phase of the network winding, induction in the reactor core, currents of two half-neutrals of the network winding, network voltage of 100 kV.

From the waveform it follows that the proposed measures can reduce the time of power discharge of the CSR from 100% -5% In to 0.3 sec, which is also a significant improvement in the dynamic characteristics of the equipment.

Thus, through the use of a transformer-converter unit with a four times increased output voltage of the converter, as compared with the analogue (1), the use of 10 Ohm resistors and the presence of an invert mode, a power reduction of 100% -5% In in 0.3 sec is provided.

As follows from the above, controlled reactors with improved dynamic characteristics have a number of advantages compared to the existing analogue (1), namely: they prevent the occurrence of overvoltage in the AC network, unnecessarily disconnect consumers sensitive to voltage levels and the rate of change, and reduce multiple exposures insulation equipment, prevent an "avalanche of voltage."

The aim of the invention is to increase the reaction rate of a controlled reactor to a change in the operating mode of the network due to faster attenuation of equalized rectified currents in the network winding in transient conditions and minimal changes in technical solutions in the converter unit.

The accelerated attenuation of equalized rectified currents in the network winding in transient conditions is achieved by adding resistive resistance to the half-neutral of the network winding. In addition, to increase the speed, transformer-converting units are used, which are connected both to the reactor control winding and to the 6-35 kV switchgear.

In the proposed device, the control functions and the functions of dynamically changing the power of the CSR are performed by different devices, for which a more powerful bias system is added, connected to the substation 6-35 kV switchgear (PS), while it carries the functions of both a converter and an inverter. The inverter functions are needed to quickly reset the reactive current of the reactor. In the patent analogue (1), these functions are not provided, which in some cases can adversely affect the stability of the system.

At the same time, a significant increase in the speed of the reactor is achieved only through a combination of resistive impedances installed in half-neutrals of the network winding and an inverter-converter connected to the substation 6-35 kV switchgear.

The use of only resistive resistances in the half-neutrals of the network winding allows to increase the speed by 2-2.5 times when gaining and resetting power.

The use of only an additional converter unit with an inversion function and with an increased output control voltage connected to a substation 6-35 kV substation allows to increase the speed of the order by 8-10 times in comparison with the existing analogue (1), however, it leads to a significant dependence of the reactor speed characteristics from power, characteristics and reliability of switchgear 6-35 kV substation.

It should be noted that in this case, the control output voltage also needs to be increased by 7-10 times, which, at the same required nominal current of the control coil, leads to an increase in the power of the converter unit, and, accordingly, in the power consumption from the switchgear 6-35 kV.

The most optimal is the bias magnetization system with an output control voltage increased by 4-5 times and an additional half-neutral resistance of 10 Ohms, which are sufficient to attenuate the equalization currents in the CO caused by a change in the mains voltage and current in the op-amp control winding. With the indicated combination of the parameters of the half-neutral resistances and the control output voltage, the speed characteristics of the controlled reactor are improved by about 20 times, which is a significant advantage over the existing analogue (1).

A further increase in the resistance of the half-neutrals of the network winding (more than 10 Ohms) practically does not give an effect and is considered inappropriate.

The proposed method for increasing the performance of CSR is used for reactors consisting of three closed single-phase rod magnetic circuits, each of which has two rods, as well as two-section СО and two-section ОУ, while the sections of СО placed on each rod are connected in parallel and connected to a three-phase network, and the three sections of the op-amp located on the same rods of the three magnetic cores are connected in series into an open triangle, while the other three sections of the op-amp, the other rods of the magnetic cores are connected In the second open triangle, two open triangles are connected in parallel and connected to an adjustable bias DC source.

To implement the method, resistive resistances in half-neutrals of the network winding, a converter-inverter connected to a substation 6-35 kV of the substation network through a transformer with an increased output voltage on the DC side, are used as an improvement, and the regulation functions are distributed between the converter blocks connected directly to the CSR and to switchgear 6-35 kV substation, which improves the dynamic characteristics of CSR, about 20 times.

Since the magnetic core of a controlled reactor can be performed in a three-phase design, the proposed method can also apply to it.

The use of the claimed invention for reactive power compensation is carried out in accordance with the following circuit diagram:

a controlled reactor (or devices using a controlled reactor) is connected to the buses of a three-phase network of 35-220 kV through a switch, consisting of two windings - a network winding and a control winding, as well as transformer-converter blocks, some of which are connected to the reactor control winding, and the other part is to a switchgear with a voltage of 6-35 kV, while the transformer-converter unit connected to the switchgear 6-35 kV has an increased output voltage of the converter, and is also able to work s in inverting mode.

The attached figure shows the “Connection diagram of equipment controlled by magnetizing a shunt reactor” 35-220 kV substation network, where

1-3 - switch,

4-6 - voltage transformers,

7-9 - current transformers,

10 - network winding

11 - resistance

12 - control winding,

13 - transformer

14 - conversion unit

15 - transformer

16 is a conversion unit

17 - automatic control system.

The following is an example implementation of the claimed invention with reference to the attached figure, which illustrates a circuit diagram of a means of reactive power compensation using the claimed invention.

To the buses of a three-phase network of 35-220 kV through a switch 1-3, a controlled reactor or devices are connected using CSR. The controlled reactor consists of two windings - the network winding 10 and the control winding 12, to which the converter blocks 14 are connected, which have alternating power supply through transformers 13.

A converter unit 16 is connected to the switchgear 6, 10 or 35 kV of the substation network via a transformer 15 with an output voltage 4–5 times higher than that of the converter 14.

The automatic control system 17, depending on the information received from voltage transformers 4-6 and current transformers 7-9, acts on the thyristors of the converter unit 14 or 16, while depending on the required control parameters, either converters 14 or a converter participate in the work 16, connected to the switchgear 6, 10 or 35 kV substation network and having more power and more output rectified voltage.

The distribution of work between the semiconductor converters 14 and 16 depends on the control parameters, i.e. from a given difference between the real voltage of the network and the voltage of the installation, which, if necessary, can be changed. With a significant change in voltage in the network, i.e. when the voltage change in the network is greater than the specified regulation statism, the converter 16 comes into operation. When the voltage change is less than the prescribed regulation statism, the converters 14 work. In both cases, the resistor 11 installed in the half-neutral of the network winding 10 allow you to respond to changes in the network with great speed. Converters 14 provide mutual "hot" redundancy.

These active resistances can be installed both in the tank of the controlled reactor and externally, while the installation options depend on the design of the electromagnetic part of the reactor — a three-phase design or a group of single-phase reactors. In the case of a three-phase design, the most preferable is the installation option inside the tank, with a group of single-phase ones, it is outside.

LITERATURE

1. Bryantsev A.M. and others. "Electric controlled by bias three-phase reactor." RF patent No. RU (11) 2132581, application No. 98100385/09, 01/06/1998. Published: June 27, 1999.

2. USSR author's certificate No. 1803934, H01F 29/14, Bulletin of inventions No. 11, 1993

Claims (1)

A way to increase the speed of the control shunt reactor, consisting of three closed single-phase rod magnetic circuits, each of which has two rods, as well as a two-section network winding and a two-section control winding, while sections of the network winding located on each rod are connected in parallel and connected to a three-phase network and the three sections of the control winding located on the same rods of the three magnetic cores are connected in series into an open triangle, while the other three sections and control windings of other magnetic core rods are connected in series into a second open triangle, with two open triangles connected in parallel and connected to an adjustable DC bias source, characterized in that resistive resistances are installed in the semi-neutrals of the controlled winding of the controlled reactor, and the parameter control functions are distributed between the converter variable power units connected to a control winding of a controlled shunt reactor, and a converter unit with an inverting function connected through a transformer to a switchgear of a substation network with an increased output voltage on the DC side.