DE19632172A1 - Three-phase transformer - Google Patents

Abstract

The transformer has respective primary and secondary windings (Upw,Vpw,Wpw),( Usw,Vsw,Wsw) for each phase, and a longitudinal regulating winding (Ul,Vl,Wl). There are two transverse regulating windings (Uq1,Vq1,Wq1),(Uq2,Vq2,Wq2) for each phase, cooperating with the primary and/or secondary windings. The longitudinal and transverse regulating windings are each provided by partial windings, in which each longitudinal regulating winding cooperates with the primary and/or secondary windings for the same phase. Each transverse regulating winding cooperates with the primary and/or secondary winding for a different phase.

Description

TECHNICAL AREA

The present invention relates to electrical energy conversion using three-phase transformers in electrical networks. It affects you Three-phase transformer, as described in the preamble of the first claim is.

TECHNOLOGICAL BACKGROUND AND PRIOR ART

In meshed electrical power supply networks or ring networks often the task of changing the power distribution in the network to one branch To protect overload or to achieve the best possible efficiency in the Total current distribution, i.e. the smallest grid losses. This will be there possible by inserting a voltage in the ring network, the circulating currents causes. The superimposition of the previous network currents with these circulating currents results in a changed current distribution in the network and thus also in the network in installed, parallel operated transformers.

The addition of an additional voltage U _z in a network branch can influence both the active power distribution and the reactive power distribution in the desired manner within the network. For this purpose, the additional voltage U _{z has} a so-called longitudinal component which is in phase with the mains voltage and a transverse component which is 90 ° out of phase with the mains voltage. A change in the longitudinal component influences the reactive power distribution in the network and the variation of the transverse component controls the active power flow.

An additional voltage U _z acting according to the above principle is usually implemented in three-phase networks by means of three-phase autotransformers, as described for example in "Electrical Machines" by Bödefeld / Sequence, Springer Verlag 1971, on pages 86ff. A normal star autotransformer with different voltage taps is used to control the series component, which is called ge in the following series transformer. The control of the transverse component is usually carried out with a triangular autotransformer, also known as a series transformer, a so-called cross-regulating transformer. Accordingly, a main transformer with a series control transformer and a series control transformer are connected in series for a combined series and transverse control in a network branch. The main transformer is used to couple the high-voltage network and the undervoltage network, and the series and series regulating transformers allow a lower-loss and therefore more economical use of parallel-connected transformers. A disadvantage of the series connection described, however, is the high production costs for the additional regulating transformers and their extensive space requirement. In addition, series and transverse regulating transformers are also lossy and, in particular, have copper and iron loss.

PRESENTATION OF THE INVENTION

The invention has for its object a three-phase transformer gangs mentioned in such a way that it is a simpler and cost-effective longitudinal and lateral control for a suitable load distribution in allows an electrical network, the for the longitudinal and lateral control required space is reduced, and compared to the prior art Reduction of the power loss should be achieved.  

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

The essence of the invention is the fact that within a three-phase trans formator housing both the required energy transfer between two gal vanically separated networks is made as well as a desired longitudinal and cross-regulation for reactive and active power distribution in an energy network is made. For this purpose it becomes a primary or a secondary phase voltage a gradually adjustable longitudinal voltage, and each a stepwise adjustable transverse voltage of the two neighboring phases added.

The advantages of the invention can be seen, inter alia, in the fact that the otherwise in order to regulate reactive and active power distribution separately in a row Main transformer switched series and cross-regulating transformers only can be reduced to a few additional windings in the main transformer. By this measure will reduce both construction costs and operating costs. At this point, the savings in construction costs include the cost-intensive ven transformer cores, the winding copper and the necessary footprint of the additional transformers. Operating cost savings are mainly due to the lower iron and copper losses.

Embodiments of the invention and the advantages that can be achieved thereby explained below with reference to the drawings.

BRIEF DESCRIPTION OF THE DRAWING

In the drawing, exemplary embodiments of the invention are shown schematically provides, namely show:

Fig. 1 is a longitudinal section of a three-phase transformer having longitudinal and transverse control windings;

Fig. 2 shows an alternative embodiment of the three-phase transformer.

Only the elements essential for understanding the invention are shown.

WAY OF CARRYING OUT THE INVENTION

In Fig. 1, E denotes the iron core of a three-phase transformer of the core transformer type. This three-phase transformer has three primary windings U _PW , V _PW and W _PW with the three phase voltages U _p , V _p and W _p and furthermore the transformer has three secondary windings U _SW , V _SW and W _SW with the three phase voltages U _s , V _s and W _s on. A longitudinal control winding U _L , V _L and W _L and two transverse control windings are also arranged on each iron core leg per phase U, V, W, namely U _Q1 , U _Q2 in phase U, V _Q1 , V _Q2 in phase V and W _Q1 , W _Q2 in phase W.

As already explained, series and transverse control transformers are used for the targeted reactive and active power distribution in an energy distribution network. According to the invention, this reactive and active power distribution is achieved by suitable electrical connections of the series control windings U _L , V _L and W _L and the cross control windings, U _Q1 , U _Q2 , V _Q1 , V _Q2 , W _Q1 , W _Q2 with the primary and secondary windings U _PW , V _PW , W _PW , U _SW , V _SW and W _SW reached. The necessary control methods for reactive and active power distribution are well known in connection with the use of conventional series and cross-regulating transformers, so that these control methods will not be explained in more detail below. The invention relates primarily to an electrical circuit to which conventional control methods can be used.

As shown in Fig. 1, the secondary winding U _{SW of} the phase U is connected via a tap changer 1 with a lying in the same phase, consisting of a number of partial windings, series winding U _L. The two secondary windings V _SW and W _{SW of} the adjacent phases V and W are electrically connected to the series control windings V _L and W _L via the tap changer 1 in accordance with the installation in phase U. The installed tap changer 1 is thus equipped in all three phases U, V, W with corresponding tap contacts for controlling the respective partial windings of the series regulating windings U _L , V _L and W _L , which a stepwise variation of the corresponding phase voltages U _s , V _s and W _s allowed. Here, all phases are varied simultaneously with only one tap changer 1 by the same amount m in pu by means of control. The added to the phase voltage U _s voltage portion of the longitudinal regulation _L U with the size m * U _s can be positive or negative depending on the selected switching position of the tap changer 1 , so that the resulting phase voltage is increased or decreased. With the control correction of the longitudinal control windings, the resulting secondary voltages are U _s + m * U _p , V _s + m * V _p and W _s + m * W _p .

A regulated change in the position of the tap changer 1 is used in an energy distribution network with a plurality of three-phase transformers operated in parallel to reduce the reactive current exchange and the losses associated therewith.

The primary winding U _PW of phase U is connected in series with the transverse control windings V _Q1 and W _Q2 . Here, too, the voltages pending at the transverse control windings V _Q1 and W _Q2 are tapped via a tap changer 2 on corresponding partial windings of the transverse control windings, the amounts of the voltages being the same, namely n * V _p and n * W _p , and variable in stages between n in pu

The phase angles of the voltages present at V _Q1 and W _Q2 are both leading or both lagging with respect to the phase voltage U _p according to the circuit diagram and position of the tap changer 2 . This is because, for example, the voltage at V _{Q1 is} tapped in phase with a selected tap changer position with the phase voltage V _p , while the added voltage at W _{Q2 is} in phase opposition to the phase voltage W _p . Thus, based on U _p, only the combinations of 60 ° leading voltage at V _Q1 with 120 ° leading voltage at W _Q2 occur, or 60 ° following voltage at W _Q2 with 120 ° leading voltage at V _Q1 , and that resulting voltage then results in U _p + n * (V _p -W _p ). The addition of the voltages to the transverse windings always results in a so-called transverse voltage which is perpendicular to U _p and which, according to a suitable regulation, is either 90 ° leading or 90 ° lagging due to the same amount and the selection of the phase angles shown. This transverse voltage is added to the phase voltage U _p , as a result of which the resulting voltage differs in magnitude and phase from U _p . This phase shift leads to a preferred active power distribution and to reduced losses.

According to the installation on the primary winding U _PW , V _PW and W _{PW are} connected via the tap changer 2 to the corresponding cross-regulating windings of the neighboring phases. So V _{PW is} connected to the cross-regulation windings W _Q1 , and U _Q2 , and W _PW is connected to U _Q1 and V _Q2 , and the resulting voltages result in V _p + n * (W _p -U _p ) and W _p + n * (U _p -V _p ).

All voltage taps on the transverse regulating windings U _Q1 , U _Q2 , V _Q1 , V _Q2 , W _Q1 , W _Q2 are operated via the one tap changer 2 and are of the same magnitude, namely n * U _p , n * W _p and n * W _p .

Fig. 2 shows an alternative embodiment of the invention. The longitudinal regulation is carried out here on the primary side of the three-phase transformer and the transverse regulation on the secondary side. Accordingly, the primary winding U _PW via the tap changer 1 is connected to the series control winding U _L and the secondary winding U _SW via the tap changer 2 with the cross-regulation windings V _Q1 and W _{Q2 of} the adjacent phases. Cyclic rotation results in the connections of the other two phases. The series control winding V _L is connected via the tap changer 1 to the primary winding V _PW , the tap changer 2 connects the secondary winding V _SW to the cross-winding W _Q1 and W _Q2 . In phase W, the series control winding U _{L is} connected via the tap changer 1 to the primary winding W _PW , and the secondary winding U _{SW is} connected to the cross-regulation windings U _Q1 and U _Q2 .

The principle of operation of this alternative solution is the same as that of the first solution shown in FIG. 1.

A combined transverse and longitudinal rain is also conceivable in the sense of the invention only on the primary side or on the secondary side of the shoot current transformer. Furthermore, the circuit arrangement according to the invention undoubtedly also in other types of transformers, such as five-legged trans Formator or jacket transformer conceivable, but of course also others Winding arrangements such as the star shown in the exemplary embodiments Star circuits are possible. The concentric arrangement of all is individual windings are not absolutely necessary, nor is their position a radial distribution prescribed on one leg of the iron frame.

Reference list

U, V, W phases
U _p , V _p , W _p phase voltages on the primary side
U _s , V _s , W _s primary phase voltages
U _PW , V _PW , W _PW primary windings
U _SW , V _SW , W _SW secondary windings
U _L , V _L , W _{L series} control windings
U _Q1 , V _Q1 , W _Q1 transverse control windings
U _Q2 , V _Q2 , W _Q2 Lateral control windings
E iron core
1 , 2 step switch

Claims (4)

1. three-phase transformer, per phase (U, V, W) at least one primary-side winding (U _PW , V _PW , W _PW ) and at least one secondary-side winding (U _SW , V _SW , W _SW ), which on a Legs of an iron core (E) are installed, the three-phase transformer for use in an electrical power transmission network with a series and / or a transverse control to achieve a suitable reactive and / or active power distribution is provided, characterized in that on each leg per phase (U, V, W) at least one longitudinal control winding (U _L , V _L , W _L ) and / or at least two transverse control windings (U _Q1 , V _Q1 , W _Q1 , U _Q2 , V _Q2 , W _Q2 ) with the primary winding (U _PW , V _PW , W _PW ) and / or the secondary winding (U _SW , V _SW , W _SW ) are in operative connection. 2. Three-phase transformer according to claim 1, characterized in that the series control winding (U _L , V _L , W _L ) either with the primary side arranged on the same leg of a phase (U, V, W) (U _PW , V _PW , W _PW ) or the secondary winding (U _SW , V _SW , W _SW ) is electrically connected. 3. Three-phase transformer according to claim 1, characterized in that either the primary-side (U _PW , V _PW , W _PW ) or the secondary-side winding (U _SW , V _SW , W _SW ), which on the leg of a phase (U, V, W) are arranged, electrically connected to at least one transverse control winding (U _Q1 , V _Q1 , W _Q1 , U _Q2 , V _Q2 , W _Q2 ) of the two adjacent phases (U, V, W). 4. Three-phase transformer according to claim 1, characterized in that the series control winding (U _L , V _L , W _L ) and the transverse control windings (U _Q1 , V _Q1 , W _Q1 , U _Q2 , V _Q2 , W _Q2 ) consist of partial windings.