SU458920A1 - Control method of static reactive power source - Google Patents

Description

The invention relates to the field of automatic regulation of power systems, in particular, to the regulation of the generated (consumed) reactive power and can be used to compensate for the reactive loads of electrical networks using static sources of reactive power (IRM).

There is a known method of controlling a static source of reactive power, containing sections made of a series-connected reactor and a frequency converter with artificial switching, by adjusting the frequency of the current in the reactor.

The aim of the invention is to expand the range of smooth control of reactive power when the limit parameters of the current frequency in the reactors are reached.

This goal is achieved by switching each of these sections alternately and changing the frequency of the current in operating reactors to the value at which the second total power in them reaches the power of a static source at the moment of switching of this section.

FIG. 1 shows a block diagram of a device implementing the proposed method; in fig. 2 - adjusting characteristic at a decrease in reactive power at the clamps of a partitioned IRM with an extended control range; in fig. 3 - the same with increasing reactive power.

A partitioned IWD consists of n equal-sized sections. Each section is connected to the network using a separate switch 1, 2, 3, ..., p and consists of a direct frequency converter with artificial switching (G, 2, 3, ..., / g),

loaded on the reactor (1, 2, 3, ..., p). The principle of operation of the device is as follows.

When the deviation of the network voltage from the nominal using the control system

the frequency of the current in the reactors 1, 2, 3, ..., n of all sections varies.

Suppose that the voltage deviation in the network has decreased. In this case, therefore, it is necessary to reduce the amount of reactive power, which is accomplished by automatically increasing the frequency of the current in the reactors (section ab of the control characteristic, Fig. 2). At the time of reaching the maximum frequency / p max (dot &), determined by the technical characteristics of the IRM, the first section is turned off (for example, the adjustment characteristic for the partitioned IRM is shown in Fig. 2,

consisting of four sections of equal power, the frequency of the current in the reactors of which varies within 2: 1).

In order for the reactive capacity at the moment of shutdown of the first section does not change, the current frequency in the reactors of the remaining three seconds must be reduced to such a value until the total power of the latter is equal to the power of the IRM at the moment of shutdown (point c). A further decrease in reactive power will pass through the cd sections (three sections operate), ef (two sections operate) and kl (one section operates). Point I corresponds to the minimum value of the power that the partitioned IRM can generate (consume).

Similarly, the sections are connected in the event of an increase in power at the IRM terminals (Fig. 3).

The analysis shows that the resulting adjustment range (Ds) of the partitioned IWM, according to the proposed icnoco6y, is increased n times in comparison with the known method.

D n-Df,

where DJ is the power control range of one section of the IWW by varying the frequency.

For the considered example, we obtain DS, i.e., four times more than with the known control method.

Subject invention

A method of controlling a static reactive power source containing sections made of a series-connected reactor and an artificial commutation frequency converter by controlling the number of operating sections and the frequency of the current in the reactor, characterized in that in order to extend the control range of the reactive power when the boundary parameters of the frequency are reached current in the reactors, alternately commute each of these sections and change the frequency of the current in operating reactors to the value at which The power in them reaches the power of the static source B at the moment of switching of the given section.

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