SU1035725A1 - Reactive power static source /its versions/ - Google Patents

Abstract

1. Static source 1nick reakg, / “ge ;;;;; : - .U- 1tivnogo M01NOSTI, containing for each phase of the network an uncontrolled circuit. of 11 series-connected uncontrolled reactors and a capacitor battery and a Managed inductive circuit, the first is connected to the mains phase, and the second to the common connection point of the capacitor battery and the unmanaged reactor, so that in order to reduce the installed power, increase reliability and eliminate higher harmonics generated by the network, the resistance of the uncontrolled reactor is 11.524, 5% of the resistance of the capacitor battery at the network frequency, and the controlled inductive circuit is not (On linear, and uncontrolled circuits are connected to an electric triangle, to the vertices of which three-phase network phases are connected, and the first is to output each of the controlled inductive circuits; it is compatible with the phase of the network that is not connected to the uncontrolled reactor that uncontrolled the circuit to which this controllable inductive circuit is connected with its second output .. from section 2. Source according to claim 1, which is based on the fact that the first outputs of controlled inductive circuits are | connected to the zero phase of the network, 3. The source according to claim 1, about tl and h anND SP. This is because the first output of each controlled inductive circuit is connected to the phase of the network connected to the top of the electric triangle, opposite to the side to which the second output of this controlled circuit is connected. 4. Source for. 1, that is, so that the controlled inductive circuits are connected in parallel with capacitor batteries. 5. Source according to paragraphs. 174, that is, due to the fact that

Description

Inductive circuits are made in the form of reactors with taps, which are connected to the network phases via switching keys.

6. The source of PP. 1-4, due to the fact that, in order to eliminate overvoltages on disconnected sections of reactors with tapes, controlled inductive circuits are made in the direction of uncontrolled reactors connected via adjustable transformers or autotransformat-i

ry

7. A static reactive power source containing for each network phase an uncontrolled circuit from a series-connected uncontrolled reactor and a capacitor battery .piSH and a controlled inductive circuit, the first output connected to the phase of the network, and the second to the common connection point of the capacitor battery and uncontrolled of the reactor under control, so that, in order to Decrease the installed capacity, increase reliability and eliminate the higher harmonics generated into the network, the resistance of the uncontrolled reactor is 11.5-24.5% ofTRE resistivity capacitors) molecular battery at a frequency network, and managed by the linear inductive circuit is formed, wherein emye uncontrolled chain connected in star, the rays which are connected phase mains ..

8. The source of claim 7, that is, with the fact that the star capacitor banks of uncontrolled circuits are connected to the star, and the first output of each controlled inductive circuit is connected to the lagging or leading phase of the network with respect to the phase connected to the uncontrolled circuit to which the second output of this controlled circuit is connected, and the connection of the first terminals of the controlled inductive circuits is carried out cyclically.

9. The source of claim 7, which is connected with the fact that unmanaged reactors of uncontrolled circuits are connected to a star, and controlled inductive circuits are connected in parallel with capacitor batteries.

10. Source of PP. 7-9, that is, with the fact that uncontrolled inductive circuits are made in the form of reactors with taps, which are connected to the network phases through the switching keys.

11. The source of PP. 7-9, characterized in that, in order to eliminate overvoltages on de-energized sections of reactors with taps, controlled inductive circuits are made in the form of uncontrolled reactors connected through adjustable transformers or autotransformers.

12. A static reactive power source containing, for each phase of the network, an unmanaged circuit from. a series-connected uncontrolled reactor and a capacitor bank and a controlled inductive circuit, the first output connected to the mains phase, and the second to the common coupling of the capacitor battery and the uncontrolled reactor, that, in order to reduce the installed power, increase reliability and eliminate the higher harmonics generated in the network, the resistance of the uncontrolled reactor is 11.5-24.5% of the resistance of the capacitor battery at the network frequency, and It is not connected to the circuit, the terminals of the reactor are connected to the phases of the network, and the capacitor banks are connected to each other in an electrical triangle.

13. The source of claim 12, which is based on the fact that the first of each controlled inductive

The circuit is connected to the lead: 1aa or lagging phase of the network with respect to the phase connected to this controlled inductive circuit through an uncontrolled reactor, and the first terminals of the controlled inductive circuits are connected cyclically.

14. The source of claim 12, wherein the first terminals of the controlled inductive circuits are connected to the zero phase of the network.

15. Source of PP. 12-14, which is characterized by the fact that non-core inductive circuits are made in the form of reactors with taps, which are connected to the network phases via the switching keys.

16. Source of PP. 12-14, which is similar to the fact that, in order to eliminate overvoltages on de-energized sections of reactors with taps, controlled inductive circuits are made in the form of uncontrolled, reactors connected via adjustable transformers or autotransformers.

The invention relates to electrical engineering and can be used to compensate for reactive power. and to stabilize the voltages in; electrical networks x.

The known static sources of reactive power (IRM}. Can be divided into two classes: I - with frequency conversion of the current in the energy storage device (capacitor or drose) II) without conversion of the frequency of the current in the storage device 5-9J.

Shortage / com iRm | class is the presence of higher harmonics in the mains current curve, which hinders their use in power grids. In addition to

First, for the practical implementation of the circuits i of these IRMs, powerful semiconductor gates with full control are needed, which are still in the development stage, as a result of which they use incompletely controlled gates, namely, thyristors with artificial switching nodes, that. leads to unjustified appreciation and reduction of devices.

The most widely used sources are And class using controlled reactors and unregulated capacitor banks.

The disadvantages of these devices are high installed power / low reliability due to the inadequacy of the capacitor battery from high harmonics} the presence of higher harmonics in the first generated current in case of controlling the power of the controlled reactors by varying the voltage on them ignition thyristors.

Inductive-capacitive sources that can also be sources of 40. reactive power, if in them instead of the load connect a controlled reactor lO

.

In current sources unmanaged j5 reactor and capacitor battery

tuned to resonance, due. This IRM, made on the basis of these sources, has a large installed capacity. In addition, ta-. .Q devices have low reliability due to the occurrence of large overvoltages on the capacitor battery and the uncontrolled reactor when the circuit breaks in the controlled reactor.

The closest in technical essence to the proposed device. is a static reactive power compensator, which consists of a series-connected 60 uncontrolled reactor and a capacitor bank and a controlled inductive circuit consisting of a reactor and phase-controlled gates with parallel-controlled (llj. 5

This scheme is obtained from the replacement circuit of a transformer reactor ..

If we proceed from such a circuit, the resistance of the uncontrolled reactor is about 50% of the resistance of the capacitor bank. For such parameters, this reactive power compensator has a large installed capacity and a low utilization rate of the capacitor battery in the mode of maximum generation of reactive power to the network (the valves are closed, as about half the power of the capacitor battery compensates for the uncontrolled reactor. With the uncertainty between the uncontrolled reactor and the capacitor battery possible resonance on one of the harmonics of the network, which leads to an overload of the capacitor battery, as well as in the presence of valves with f znym control that will generate higher harmonic current, autoparametric rise to vibrations. In addition, the regulation of inductive power

i controlled reactor using these valves with phase control leads to the generation of higher current harmonics in the supply network, which also overload the capacitor battery, which leads to a decrease in its reliability.

The aim of the invention is to reduce the installed power, increase reliability and eliminate the high harmonics of the current generated in the network ....

In the first embodiment, in a static reactive power source containing, for each phase, an uncontrolled network of a series-connected uncontrolled reactor and a condenser battery and a controlled inductive circuit connected to the mains phase and the second to a common connection point capacitor bank and uncontrolled reactor, the resistance of the uncontrolled reactor is 11.5-24.5% of the resistance of the capacitor battery at the mains frequency, and the controllable inductive circuit is linear, with than uncontrolled circuits are connected in an electrical triangle, to the vertices of which the phases of a three-phase network are connected, and the first output of each of the controlled inductive circuits is connected: to the network phase that is not connected to the uncontrolled reactor of the uncontrolled circuit to which the control is inductive circuit its second conclusion. in order to reduce the voltage on the capacitor batteries while reducing the reactive power generated to the network, the first terminals of the controlled circuits are connected to the zero phase network,

In order to reduce the installed capacity of the capacitor banks, the first output of each controlled inductive circuit is connected to the phase of the circuit connected to the top of the electric triangle opposite to the side to which the second output of this controlled circuit is connected. Controlled inductive circuits are also connected in parallel with capacitor banks.

In the second embodiment, in a static reactive power source containing for each network phase an uncontrolled circuit from a series-connected uncontrolled reactor and a capacitor battery and a controlled inductive circuit, the first output connected to the network phase, and the second to the common connection point of the capacitor battery and the uncontrolled reactor, the resistance of the uncontrolled reactor is 11.5-24.5% of the capacitance of the capacitor bank resistivity at the mains frequency, and the controlled inductive circuit is linear, with it does not .upravl emye circuits are connected in a star connected to the rays which phase mains.

The star is connected to the capacitor banks of the uncontrolled circuits, and the first output of each controlled inductive circuit is connected to the lagging or leading phase of the network with respect to the phase connected to the uncontrolled circuit to which the second output of this controlled inductive circuit is connected; moreover, the connection of the first conclusions controlled inductive circuits carried out cyclically.

Uncontrolled reactors of uncontrolled circuits are connected to a star, and controlled inductive circuits are connected in parallel with capacitor batteries,. In the third embodiment, a static reactive power source comprising for each phase of the network an uncontrolled circuit of a series-connected uncontrolled reactor and a capacitor battery and a controlled inductive circuit connected by the first phase to the network phase. the second .- to the common connection point of the capacitor battery and uncontrolled peeiKTopa, the resistance of the uncontrolled reactor is li, 524, 5% of the resistance of the capacitor battery at the mains frequency, and the controlled inductive circuit is linear, and the uncontrolled circuits with reactor leads are connected to fuzzy, network, and capacitor banks are interconnected in an electric triangle.

The first output of each controlled inductive circuit is connected to the lead-in. the lean or lagging phase of the network in relation to the phase connected to this controlled inductive circuit through an uncontrolled reactor, and the connection of the first terminals of the controlled inductive circuits is carried out cyclically,

The first terminals of the controlled inductive circuits are connected to the zero phase of the network.

For all three variants of a static reactive power source, uncontrolled inductive circuits can be made in the form of reactors with taps that are connected to the network phases via switching keys (for example, thyristor).

In order to eliminate overvoltages on de-energized sections of reactors with taps, the controlled inductive circuits are made in the form of uncontrolled reactors connected through adjustable transformers or autotransformers.

FIG. 1 is a schematic diagram of the IRM according to the first embodiment of FIG. 2 - the same, when connecting the first terminals of the controlled inductive circuits to the zero one in FIG. 3, the same when connecting the first output of each controlled circuit to the phase of the network connected to the top of the electrical triangle opposite to the side to which connected to the second output of this. controlled circuit; Fig. 4 is the same when connecting controlled inductive circuits parallel to a capacitor battery m / Fig. 5 is a schematic diagram of the IRM according to the second embodiment; fig, b - the same, when connecting capacitor banks to the automobile and connecting the first terminals of each controlled inductive

of a circuit to a lagging phase in relation to the phase connected to that uncontrolled circuit to which the second output of this controlled circuit is connected, in FIG. 7, the same, when connected to a star of uncontrolled reactors and when connecting controlled inductive circuits parallel to capacitor batteries, in fig. 8 is a schematic diagram of the IWD according to the third embodiment in fig. 9, the same, when connecting the first terminal of each controlled inductive circuit

jK of the advanced phase of the network with respect to the phase connected to this controlled inductive circuit via an uncontrolled reactor / in FIG. 10 - the same, when the first terminals of the controlled circuits are connected to the zero phase of the network. FIG. 11 - controlled induction on a circuit made in the form of a reactor with a 1cam / in fig. 12 - controlled inductive circuit, made in the form of an unmanaged reactor, which is connected via an adjustable transformer. FIG. 1-10 marked: A, B, G phase, network; L, L, L — j — unmanaged reactors; The zero-phase of a network of 1,2,3 g-phases of the network, which are connected to the first terminals of controlled inductive circuits, C., L-L controls the inductive, Ca, capacitor batteries. In FIG. 10 .12, it is indicated: L - reactor with tapes 1C. - switching keys} LJ, uncontrolled reactor, TR - transformer. . The proposed power sources are as follows. When the power of controlled inductive circuits changes, the reactive power given to the network, which is defined by the expression, changes. - Qa- 2 Q (1) where a. - total capacity of capacitor batteries, 7 Q ,, - sukmarna power of uncontrolled reactors, Qj, j - total power of controlled inductive circuits. Controlled inductive circuits are linear. A reactor with tapings is proposed (Fig. 117. In this case, its power is determined by the inductive resistance when the 1st tap is connected. When the reactor is completely turned off, we obtain the maximum power generated in the network. The tap-off reactor is a disadvantage with the presence of overvoltages in the disconnected part of the reactor. To avoid these unwanted overvoltages, an uncontrolled reactor connected through an adjustable transformer can be used as a controlled inductive circuit or switch or autotransformer. Both contact and contactless switches (for example, thyristor switches) can be used as switching keys, the latter being more promising due to their speed. Non-controlled reactors are designed to protect capacitor banks from high harmonic currents, which greatly increases reliability IRM. The value of inductive resistance of uncontrolled reactors is selected taking into account the level of higher harmonics in the network and the magnitude of the allowable overload current of capacitor banks from the condition W .JV ,, o, . - fwxr K – y 4 C. lu C i L where 1, is the current of the capacitor battery j t1Ю maximum permissible current of the condenser battery; , is the voltage of the i-th harmonic, i is the order number of the harmonic x, is the resistance of the capacitor battery at the first harmonic, XL, is the resistance of the uncontrolled reactor at the first harmonic, and n is the limit value of the order number taken into account in the calculation of the harmonic. . X In the case if -r-x., Then t is the resonance mode at the 1st harmonic (we do not take into account active resistances because of their smallness) .1 Therefore, the reactor resistance must be chosen so as not to get into resonance at the first or higher harmonics. When the resistance of the controlled inductive circuit changes, the intrinsic resonant frequency of the IWM will change somewhat. Therefore, the resistance of the uncontrolled reactor is determined from expression (2) only tentatively. Its final choice can be made by checking condition 7f y for the entire range of reactive power control. As the calculations show, the resistance at the first harmonic of the uncontrolled reactor is selected in the range of 11.5-24.5% of the resistance of the capacitor battery, also at the first harmonic. The proposed IRM allows both generating and consuming reactive power. By reducing the resistance of the controlled reactor, it is possible to switch to the mode of reactive power consumption. This mode is achieved when capacitor batteries are disconnected. In this case, the installed power of the controlled reactor is reduced. By reducing the amount of reactive power generated in the network, the voltage on the capacitor batteries decreases, which leads to an increase in the reliability of the latter. The number of you-t. Strokes of capacitor batteries is a function of voltage 5-7 degrees tlOj. The diagrams shown in FIG. 2, 3, 4, б, 7, 9 and 10 have different installation power (the difference does not exceed 5%), different utilization factors of the capacitor bank (not more than 15), i which are determined by the resistance of the uncontrolled reactor, different ranges of the resonant frequency. Therefore, the choice of the IRM scheme should be made by analyzing and determining the most optimal IRM scheme, taking into account the specific network parameters. : Effect of using proposed static reactive sources

power compared to the known ones is to increase the reliability of capacitor banks, which are the most unreliable elements in static RWM; in reducing the installed capacity in the absence of

L

higher harmonics generated in a network of reactive current.

The proposed IRM can be used both by power systems in power centers and by consumers of electrical energy. FIG.

l L - -.

H T 2-G-VT

Claims (16)

1. A static source of reactive power, containing for each phase of the network an uncontrolled circuit of series-connected uncontrolled reactor and capacitor bank and a controlled inductive circuit, the first output connected to the phase of the network, and the second to the common connection point of the capacitor bank and uncontrolled reactor, o The reason is that, in order to reduce the installed power, increase reliability and eliminate higher harmonics, the generator. mains voltage, the resistance of an uncontrolled reactor is 11.524.5% of the resistance of the capacitor bank at the mains frequency, and the controlled inductive circuit is linear, and the uncontrolled circuits are connected into an electric triangle, the phases of the three-phase network are connected to the vertices of the circuit, and the first output of each of the controlled inductive circuits is connected to the phase of the network, not connected to the uncontrolled reactor of that uncontrolled "circuit, to which this controlled inductive circuit is connected by its second output. ·. , 2. Source for π. 1, with the fact that the first outputs of controlled inductive circuits are connected to the zero phase of the network. 3. Source for π. 1, it is important that the first terminal of each controlled inductive circuit is connected to the phase of the network connected to the top of the electric triangle, opposite to the side to which the second terminal of this controlled circuit is connected. 4. Source according to p. 1, with the fact that controlled inductive circuits are connected in parallel with capacitor banks. 5. Source according to paragraphs. 1? 4, with the fact that the uncontrolled, inductive circuits are made in the form of reactors with solders, which are connected through the switching keys to the phases of the network. 6. Source according to paragraphs. 1-4, which is deprived of the fact that, in order to eliminate overvoltages in the de-energized sections of the sealed reactors, controlled inductive circuits are made in the Vila of uncontrolled reactors connected via controlled transformers or autotransformers. 7. A static source of reactive power, containing for each phase of the network an uncontrolled circuit of series-connected uncontrolled reactor and capacitor bank and a controlled inductive circuit, the first output connected to the phase of the network, and the second to the common point of connection of the capacitor bank and uncontrolled reactor, characterized in that, in order to reduce installed power, increase reliability and eliminate higher harmonics generated in the network, the resistance of an uncontrolled reactor is 11.5-24.5% of Lenia capacitor bank at a frequency network, and managed by the linear inductive circuit is formed, wherein the unmanaged circuit connected in star, the rays which are connected phase mains. 8. The source according to claim. 7, l and m of h a- and w ¹ w I th with the fact that a star connected capacitor batteries unmanaged chains, and the first terminal of each controllable inductive circuit connected to the advanced or lagging phase network with respect to phase connected to that uncontrolled circuit to which the second terminal of this controlled circuit is connected, and the first terminals of controlled inductive circuits are connected cyclically. 9. The source according to claim 7, with the fact that uncontrolled reactors of uncontrolled circuits are connected to the star, and controlled inductive circuits are connected in parallel with capacitor banks. 10. The source according to paragraphs. 7-9, Casting 'by the fact that uncontrolled inductive circuits are made in the form of reactors with taps, which are connected through the switching keys to the phases of the network. 11. Source according to paragraphs. 7-9, characterized in that, in order to eliminate overvoltages on de-energized sections of the sealed reactors, controlled inductive circuits are made in the form of uncontrolled reactors connected through adjustable transformers or autotransformers. 12. A static source of reactive power, containing, for each phase of the network, an uncontrolled circuit from. of an uncontrolled reactor and a capacitor bank connected in series and a controlled inductive circuit connected first to the phase of the network and the second to the common connection path of the capacitor bank and uncontrolled reactor, which means that, in order to reduce the installed power, increase reliability and elimination of higher harmonics generated in the network, the resistance of an uncontrolled reactor is 11.5-24.5% of the resistance of a capacitor bank at the network frequency, and a controlled inductive circuit. made linear, with uncontrolled circuit leads of the reactors connected to the phases of the network, and capacitor banks are interconnected in an electric triangle. 13. The source according to claim 12, wherein the first output of each controlled inductive circuit is connected to the leading or lagging phase of the network with respect to the phase connected to this controlled inductive circuit through an uncontrolled reactor, and the connection of the first leads of the controlled inductive circuits carried out cyclically. 14. The source according to p. 12, characterized in that the first outputs of the controlled inductive circuits are connected to the zero phase of the network. 15. The source according to paragraphs. 12-14, characterized in that the uncontrolled inductive circuits are made in the form of reactors with taps that are connected through the switching keys to the phases of the network. · 16. Source according to paragraphs. 12-14, characterized in that, in order to eliminate overvoltages in the de-energized sections of the reactors with taps, controlled inductive circuits are made in the form of uncontrolled; reactors connected via controlled transformers or autotransformers.