RU136919U1 - MAGNETIC CONTROLLED BYPASS REACTOR - Google Patents

Abstract

A device controlled by magnetization of a shunt reactor containing split network windings located on different rods of the magnetic circuit and connected to the neutral terminals of the reactor, a DC bias source, the DC poles of which are connected to the neutral terminals of the reactor, and the AC input to the terminals of the reactor compensation winding through an intermediate transformer, control, regulation, protection and automation system, neutral reactors included between neutral reactor leads and ground, characterized in that between the terminals of the compensation winding of the reactor and ground are connected in series a circuit breaker and a boost reactor, and the control, regulation, protection and automation system is connected to the control circuit of the circuit breaker and the output circuits of the relay protection and automation system of the substation.

Description

The claimed technical solution relates to electrical engineering, and in particular to devices controlled by magnetization of shunt reactors (CSR), which are complexes of electrical equipment to compensate for reactive power and stabilize the voltage of high-voltage power lines (power lines). The CSR contains an electromagnetic part, a magnetizing system converter with a control, regulation, protection and automation system, an intermediate converter power transformer, switching and protective equipment, and the claimed technical solution relates to a CSR, the electromagnetic part of which has network windings used simultaneously and as magnetization windings.

Known devices of shunt reactors, the network windings of which are used simultaneously and as magnetization windings (V. Chvanov. A controlled shunt reactor is a control object. ELECTRO. Electrical engineering, electric power industry, electrical industry. No. 2, 2008, p. 38, Fig. 1. [ one]). Each phase of a controlled reactor of this type consists of two half phases, the windings of which are located on two different rods of the magnetic circuit. The high-voltage leads of the half-phase windings are connected and connected through the high-voltage input to the phases of the network using high-voltage switches. The neutral leads of the half-phase windings have separate leads from the reactor tank. The neutral terminals of the network windings of the three phases of the reactors are connected in three, forming a connection diagram of the network windings "double star with split neutral", and are grounded through a neutral reactor.

Between the neutral terminals of a three-phase controlled reactor, a controlled thyristor converter (rectifier-inverter) of the magnetization system is switched on.

The converter can be powered from the triangle of the compensation coil of the CSR through a converter transformer, matching the parameters of the converter and the compensation coil of the CSR according to voltage levels, or from the substation's own needs network.

The option of supplying the converter from the auxiliary system or an external electrical network requires solving the problem of ensuring the quality of the voltage in the network supplying the converter, and, in a number of cases, increasing the power of the auxiliary system. The option of supplying the converter from the triangle of the compensation winding is preferable, since it does not require a solution to these problems. In this embodiment, the thyristor converter circuit can be the simplest - 6-pulse, which simplifies and minimizes the cost of the bias system. However, with this option of supplying the converter, it is difficult to force the reactor power at the moment of switching on, which is especially important for using CSR as a linear reactor in the modes of switching on the power lines to idle, when reactors are one of the main means of limiting overvoltages at the end of the switched power lines, because Until the moment the power line is turned on, there is no magnetization of the rods of the reactor magnetic circuit, which corresponds to the minimum CSR power and the minimum effect on the limitation of overvoltages at the time of switching on the power line.

Known magnetization-controlled CSRs in which the converter is powered from a triangle of the compensation coil of CSR through a converter transformer matching the parameters of the converter and compensation coil of CSR according to voltage levels, and from the substation’s auxiliary network (Magnetically controlled electric reactors. Collection of articles. Ed. Doctors of Engineering Sciences, Prof. A.M. Bryantsev. M: “Sign.” 2004, 264 p. [2]).

In these CSRs, in order to increase the speed of gaining power at the moment of switching on, an additional converter of lower power, powered by the auxiliary system of the substation, is introduced into the structure of the magnetization of the CSR, which provides preliminary magnetization of the rods of the reactor magnetic circuit (before applying voltage to the power lines), due to which the CSR practically immediately turns on with a power close to the nominal. However, these technical solutions relate to CShRs having separate magnetization (control) windings.

In CSR, the network windings of which are used simultaneously and as magnetization windings, the equipment of the magnetization system must have a class of isolation of the neutrals of the reactor network windings. For example, for a CSR with a voltage of 500 kV, the insulation class of the neutrals to which the converter of the magnetization system is connected is 35 kV. Under these conditions, the parallel operation of high-voltage converters, one of which is supplied from the substation's own needs system, and the other from the compensation winding through converter transformers of different voltage classes, taking into account the need to install appropriate protective switching devices, leads to a significant complication and cost of the magnetization system, as well as significant increases in it losses of active power. In addition, given that the converter, which provides preliminary magnetization when the reactor is connected to the network, works extremely rarely, the application of this technical solution is unacceptable from both a technical and economic point of view.

The closest in technical essence to the claimed device is a CSR, the network windings of which are used simultaneously as magnetization windings, and the magnetization system can be powered both from the compensation winding of the reactor and from an external network due to the presence of special high-voltage switching devices (switches) in the power circuit (Budargin O.M., Makarevich L.V., Mastryukov L.A. Controlled saturable reactor with a capacity of 180 MVA, voltage of 500 kV OJSC ELECTROZAVOD. ELECTRO. Electrical engineering, electric power industry a, electrical industry.No.6, 2012, p. 28, Fig. 1. [3]), adopted as a prototype.

In this CSR, when the bias system is operated from an external network, it is possible to pre-magnetize the rods of the reactor magnetic circuit (before applying voltage to the power lines), due to which the CSR turns on almost immediately with a power close to the nominal value. However, since the specified requirements for the speed of maintaining voltage during changes in the operating power line mode are only provided when the bias system is powered from the compensation winding, after the power line is turned on and the steady-state operation mode is reached, the CSR magnetization system must be transferred from the external mains to the power from the compensation winding . Such a transition is accompanied by a dumping of the reactor power for the time necessary for technological operations to turn off and turn on the high-voltage switching devices that provide the required type of power for the magnetization system.

The aim of the invention is to improve performance when turned on with the exception of these disadvantages.

The technical result of the claimed invention is to increase the speed when turning on the CSR when the bias system is powered only from the compensation winding of the reactor and increase the reliability by reducing the electrical effects on the valves of the converter of the bias system.

The specified technical result is achieved due to the fact that in the known CSR device containing split network windings located on different terminals of the magnetic circuit and connected to the neutral terminals, a DC bias source, the DC poles of which are connected to the neutral terminals of the reactor, and the AC input to the terminals of the compensation winding through an intermediate transformer, a control, regulation, protection and automation system, neutral reactors connected between neutral and ground terminals of the reactor and, further compensation between the terminals of the reactor winding and ground are series-connected switch and booster reactor, wherein the control system, regulation, protection and automatics is connected to switch control circuits and output circuits relaying substation automation system.

Known technical solutions with such signs were not found. A diagram of the proposed CSR is shown in FIG. one.

Each phase 1 of the three-phase controlled shunt reactor shown in FIG. 1, contains a common magnetic system with two rods and a split network winding 2, 3 and compensation winding sections 4, 5 located on them. The network windings of the rods have a common high-voltage line terminal and two neutral terminals output to the shunt reactor tank cover, as well as compensation winding leads. A neutral reactor 6 and a direct current output of the bias source converter 7 with a control, regulation, protection and automation system CSR 8 are connected to the neutral terminals of the reactor 8. The terminals of the compensation windings of the three phases of the shunt reactor are assembled in a triangle to compensate for harmonics that are multiples of 3 in the phase current of the reactor. the same terminals are connected to an intermediate transformer 9 supplying the AC input of the converter of the bias source 7. To the terminals of the compensation windings of the three phases of the shunt Ktorov booster connected three-phase reactor 10 through the switch 11, whose control circuits are connected to the control system, regulation, protection and automatics CSR 8, connected to the output circuits relaying substation automation system and 12 ..

The bias-controlled CSR shown in FIG. 1, works as follows. When the CSR switch is disconnected from the side of the network winding or in the absence of voltage on the power lines, there is also no voltage on the compensation winding of the reactor, and, consequently, the magnetization of the reactor. In normal mode, when the CSR switch is turned on from the side of the network winding and if there is voltage on the power transmission line, there is voltage on the compensation winding of the reactor and the bias converter by changing the bias current changes the reactor power, maintaining the bus voltage with a speed determined by the bias system parameters and characteristics the electromagnetic part of the reactor. For reactors with a rated voltage of 220-500 kV, the speed response, characterized by the time of power gain and discharge from minimum to nominal value, as well as from nominal to minimum value, as a rule, is set by the customer and is about 0.3 sec.

A controlled shunt reactor is connected to an existing power line, to exclude the influence of strong electromagnetic disturbances on the power line operating mode, with a minimum power (reactor idle mode) with a further increase in power in accordance with the requirements of the dispatcher, which sets the appropriate settings in the voltage control CSR system power or current.

Maximum speed (power boost) is required from a controlled shunt reactor in modes accompanied by overvoltages on power transmission line equipment. First of all, this is important when using the CSR as a linear reactor in the modes of turning on the power line (power transmission line) to idle, as well as when automatically reconnecting (AR) the line, when reactors are one of the main means of limiting overvoltages at the end of a switched power line. At the same time, the speed of the reactor determines the duration of the overvoltage on the equipment and the decrease in the energy released in the surge arresters (AR), protecting them from damage. These modes occur under the control of dispatch personnel, power line automation and substations, allowing you to coordinate the operation of this automation with the control system and automation of CSR. The connection of the boosting reactor to the compensation winding, when high voltage is applied to the network windings of the shunt reactor (when the reactor is excited), leads to a sharp decrease in the resistance of the reactor due to the demagnetizing effect of the compensation winding loaded on the resistance of the boosting reactor, and, accordingly, to an increase in the power consumed by the reactor. Before turning on the power line at idle and in the event of a short circuit, in the automatic reclosure pause, the control circuit control system, having received a signal from the relay protection system and the substation automation, sends a command to turn on the boost reactor circuit breaker, so when the voltage appears on the inputs, the reactor goes into inertia mode maximum reactive power due to dissipation reactance between mains and compensation windings, as well as boost reactor reactance, providing maximum limitation of voltage arising in this mode. The magnitude of the reactance of the boosting reactor is selected taking into account reliable detuning from the action of the maximum current protection of the compensation winding from short circuit at its terminals. An additional effect of turning on the boosting reactor and favorable for the converter of the magnetization system is that the load on the compensation winding of the CSR at the time of switching on reduces the overvoltage on the converter valves, which increases the reliability of its operation. After the voltage appears on the valves of the converter, its control and regulation system forces the rectified voltage of the converter, which leads to an increase in the bias current. After reaching the set value of the bias current, the control system generates a signal to turn off the boost reactor switch and the boost reactor is turned off. The further operating mode of the shunt reactor will be determined by the selected algorithm of the control system for CSR. Considering that the maximum amplitudes of overvoltage when switching on power lines are observed in the first 1-2 half-periods of the network frequency, and the bias converter provides a set of reactor power in about 0.3 seconds, the duration of switching on under the boost reactor voltage is not more than 0.2-0, 3 sec As a result, the installed power of the boosting reactor is much less than its short-term maximum power, and the dimensions are small, because the level of isolation of the boost reactor, corresponding to the insulation level of the neutral of the shunt reactor, is significantly lower than the insulation level of the network winding of the CSR.

The claimed technical solution was investigated on mathematical models of magnetically controlled shunt reactor and showed high efficiency for increasing the speed of controlled shunt reactors used to compensate for reactive power and voltage regulation on high-voltage AC power lines and substations of electric power systems.

Information sources:

1. Chvanov V.A. A controlled shunt reactor is a control object. ELECTRO. Electrical engineering, electric power industry, electrical industry. No. 2, 2008, p. 38, Fig. one.

2. Bias-controlled electrical reactors. Digest of articles. Ed. Doctors of tech. sciences prof. A.M. Bryantseva. M. The Sign. 2004, 264 p.

3. Budargin O.M., Makarevich L.V., Mastryukov L.A. Managed saturable reactor with a capacity of 180 MVA, voltage of 500 kV, OJSC ELECTROZAVOD. ELECTRO. Electrical engineering, electric power industry, electrical industry. No. 6, 2012, p. 28, fig. one.

Claims (1)

A device controlled by magnetization of a shunt reactor containing split network windings located on different rods of the magnetic circuit and connected to the neutral terminals of the reactor, a DC bias source, the DC poles of which are connected to the neutral terminals of the reactor, and the AC input to the terminals of the reactor compensation winding through an intermediate transformer, control, regulation, protection and automation system, neutral reactors included between neutral reactor leads and ground, characterized in that between the terminals of the compensation winding of the reactor and ground are connected in series a circuit breaker and a boost reactor, and the control, regulation, protection and automation system is connected to the control circuit of the circuit breaker and the output circuits of the relay protection and automation system of the substation.

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