DE19748147A1 - Static compensator for reactive power compensation in electrical power supply network - Google Patents

Abstract

The static compensator is connected to a magnetic foot of a step-down transformer (5) between network voltage planes. The compensator comprises a thyristor regulator (6) connected to a stray winding (5a). The stray winding may be arranged axially on a laminated core of the step-down transformer adjacent to a primary and/or secondary winding.

Description

TECHNICAL AREA

The invention relates to a static compensator for fast Reactive power control of electrical energy transmission networks. In the Invention is based on a static compensator according to the Preamble of claim 1.

Static compensator devices of the type mentioned are for example known from the Cigré Paper 12-05, 1978, "REALTOR TRANSFORMER FOR CONTROLLABLE STATIC COMPENSATORS ".

TECHNOLOGICAL BACKGROUND AND PRIOR ART

Static compensators, also called SVC (Static Var Source), are Devices for fast reactive power regulation or control the before were developed almost thirty years ago and have become an established standard Are technology. There are two main types different mode of action and different behavior. Both  What is common is that they run parallel to the consumer network operated by means of a step-down transformer and an upstream control panel become.

A first embodiment comprises thyristor-controlled chokes (TCR thyristor Controlled Reactor), in which the current in the throttle can be regulated continuously. Find another Thyristor switched capacitor banks (TSC thyristor switched capacitors) Use, however, because of the inevitable Inrush current surges are not used can. The capacitor banks are either connected by means of thyristor or switched off, the switch-on time being selected so that none Inrush currents occur. That is why only full-stage switching possible.

In practice, fixed capacitor banks are often used also serve as harmonic filters, and the TCR variant for infinitely variable Control. Sometimes both variants are combined, especially then when the necessary capacitive operating range is the same or is larger than the inductive range and the choke as well as the associated one Power electronic actuator is therefore an uneconomically large one Should have construction work.

In the early days of the development of expansion joints, people thought also because instead of a transformer choke Combination to use a stray transformer, its secondary winding was short-circuited by means of thyristor controllers. These transformers were built similar to normal transformers, so with concentric winding arrangement. The necessary large spread was essentially achieved by an oversized spreading gap. Such a transformer design is described for example in Cigré Paper 12-05 / 1978, "Reactor Transformer for Controllable Static  Compensators ". Transformer compensators as they are known in the art described here, could not because of lack of economy prevail compared to the Thyristor Controlled Reactors and the Thyristor switched capacitors. However, the effort for that Provision of a conventional compensator unit by means of Step-down transformer in connection with chokes and / or capacitors also considerable in terms of investment costs and space requirements.

PRESENTATION OF THE INVENTION

The object of the invention is to avoid the disadvantages mentioned means to design a static compensator that comparatively to the state of the art the effort for the space requirement and the costs for a compensator can be significantly reduced and also the Compensator is significantly simplified.

According to the invention, the object is achieved by the features of the first claim solved.

The advantages of the invention can be seen, inter alia, in that the Integration of a stray winding in a step-down transformer Reactive power compensation between electrical power supply networks can be done in the simplest way. The compensation of the reactive power is directly between the mains voltage levels in the step-down transformer controlled via thyristor actuators connected to the stray winding compensated. Compared to the prior art, this is unnecessary Installation of a separate path for a static Compensation device of conventional type, comprising an associated Panel, a separate step-down transformer and a corresponding one inductive load built as a choke. Beyond the savings mentioned then there is no longer a need for a corresponding one  Installation space. It also stands for reactive power compensation The transformer used, of course, also the Power transmission between an energy transmission network and one Consumer network available.

A particularly preferred embodiment of the invention provides that the Stray winding on the core core of the step-down transformer axially in addition to the primary and concentrically arranged Secondary windings is located. Such a transformer with Stray winding is essentially the same in terms of its structure conventional step-down transformer with a magnetic one Useful flux coupled stray winding is provided, this stray winding not arranged concentrically to the main windings of the transformer but axially next to it. By such an axially adjacent arrangement the desired size of the stray impedance is also simple adjustable.

A further embodiment of the invention provides for the stray winding in a step-down transformer concentric with the primary and To arrange secondary windings.

BRIEF DESCRIPTION OF THE DRAWING

The invention is explained in more detail below using an exemplary embodiment explained, namely shows

Fig. 1 is a schematic illustration of the coupling of a power transmission network to a consumer network in consideration of an inventive compensation of reactive power by means of a static compensator;

Fig. 2 is a sectional view of a static compensator according to the invention.

They are only the elements essential for understanding the invention shown.

WAY OF CARRYING OUT THE INVENTION

In Fig. 1 of an electric power transmission network 1 are designated by high-voltage lines which are connected via switching boxes 3 having a busbar 2. The busbar 2 in turn, with the interposition of switch panels 3, has outlets which, for example, lead to a harmonic filter 4 and a downstream line voltage level 7 . The harmonic filter 4 typically consists of a combination of a resistor, a coil and a capacitor.

The busbar outlet to the downstream line voltage level 7 fulfills a double function: on the one hand, the energy transmission from the busbar 2 to the line voltage level 7 takes place via a step-down transformer 5 , and on the other hand the reactive power required in the downstream line voltage level 7 is compensated by means of a stray winding 5 a, which is supplied by one Thyristor actuator 6 is controlled. The step-down transformer is enclosed between panels 3 in accordance with electrical protection regulations.

The scattering winding 5a is linked directly in the step-down transformer 5 on the sheet stack core with the magnetic useful flux for energy transfer. The inventive coupling of stray winding 5 with a useful flux is achieved in that the stray winding 5 is located on the sheet a packet core axially adjacent to the typically concentric with each other for a step-down transformer 5 arranged primary and secondary windings. Such an arrangement allows easy adjustment of the stray impedance size. The control of the current flow through the stray winding 5 a is achieved with the thyristor actuator, which achieves a reactive power compensation which is adapted to the requirements in the downstream mains voltage level 7 . Any reactive power requirement of a consumer 7 in the immediate vicinity of the consumer network can thus be compensated for in a quick and simple manner.

In addition, compared to the prior art, there is no need to install a separate path for a conventional static compensation device. Compared to the relatively low overhead of the stray winding 5 in a step-down transformer 5, necessary for conventional compensators cost of a panel, a separate down transformer and a corresponding throttle can be saved. In addition to the savings mentioned, there is no longer any need for an appropriate installation space for conventional expansion joints. In addition, the step-down transformer used for reactive power compensation is of course fully available for energy transmission between the busbar 2 and the consumer 7 . The static compensator according to the invention for reactive power compensation in power supply networks can be referred to as an "integrated compensator" due to its implementation within a step-down transformer 5 .

Fig. 2 shows an example of an embodiment of the invention using a step-down transformer with integrated stray winding. On an iron frame 9 of a three-phase transformer, the main windings 8 a, b are arranged concentrically on legs. In addition to each pair of windings consisting of these main windings 8 a, b, stray windings 5 a are installed on the legs according to the invention. A thyristor actuator for regulated current application to the stray windings 5 a is not shown, since such devices are well known in connection with the prior art.

Conceivable within the scope of the invention is also that the scattering windings are arranged only above or below the skin windings 8 a, b, or that in a step-down transformer 5 to the main windings stray winding a concentrically installed. 5

Reference list

1

Power lines

2nd

Busbar

3rd

Panels

4th

Harmonic filter (suction circuit)

5

Step-down transformer

5

Spreading

6

Thyristor actuator

7

Subordinate line voltage level, consumers

8th

a, b main winding

9

Iron frame

Claims (3)

1. Static compensator for reactive power compensation in electrical power supply networks, wherein different supply voltage levels are coupled by means of a stepdown transformer (5), a comprises which static compensator having a stray winding (5 a) in operative connection standing Thyristorstellglied (6), characterized in that the stray winding ( 5 a) is in operative connection with a magnetic foot of the step-down transformer ( 5 ) between the mains voltage levels. 2. Static compensator according to claim 1 characterized in that the stray winding (5a) arranged on a laminated core of the stepdown transformer (5) is axially adjacent to a primary and / or secondary winding of stepdown transformer (5). 3. Static compensator according to claim 1 characterized in that the stray winding (5a) disposed on the laminated core of the stepdown transformer (5) radially concentric with the primary and / or secondary winding of stepdown transformer (5).