DE489953C - Three-winding series step transformer for stepwise addition or reduction of voltages of adjustable phase and size - Google Patents

Description

Three-winding series step transformer for stepwise or Reduction of voltages of adjustable phase and size Gradual addition or reduction of voltage values in a three-phase network can be done in a known manner with step transformers take place, the windings of which directly into the main circuit without intermediate transformers are switched on and their excitation from the network itself or from a third party Power source is taken. Here you have to, depending on whether the voltage change parallel to the direction of the phase voltage (for the purpose of voltage regulation) or perpendicular to this (for the purpose of angle control), the excitation winding in a well-known way in one of your. Basic star or delta circuits switch with a vector equivalent switching type. It is difficult for me to develop if one regulates both the parallel and the perpendicular to the phase voltage Row-step winding on the same leg, which naturally only wants an excitation circuit (either star or delta or one of these basic circuits vectoritell equivalent switching type).

The winding arrangement described below eliminates this difficulty in that in one of the two series-step windings, each step is separate divided into two winding groups, which are housed on two adjacent legs and are connected in series. It becomes like the familiar one Zigzag circuit achieved that, for example, despite the excitation winding connected in a triangle (B in Fig. T) a series tap winding A connected in an open star is created. the second series tap winding C can in this case the known open delta connection exhibit. In an analogous way one can with the field winding connected in star according to Fig. a the series step winding regulating parallel to the phase direction Perform A in an open position, as is common practice, and the one that regulates perpendicular to it Row-step winding C now in half, one behind the other, over two corresponding legs lead, so that an open triangular winding is formed.

Both figs. R and a represent the strongly drawn out lines represent the individual windings, namely: B the excitation winding, A the in. Direction the phase voltage and C the series step winding regulating perpendicular thereto. the The phase position of the partial voltages corresponds to the vectorial direction in the @obelren Halves of the illustration drawn winding parts. The supply and discharge of the streams takes place in the usual way with series step transformers with the help of lines marked by arrows. With the above: schematic part of Fig. r and a, which apart from the excitation winding B, both series-step windings A and C, the power lines are only drawn for one phase. the Crossing of the step tapping with the power line should indicate that this optionally using a diverter switch or the like with the individual stages can be connected.

In the circuit diagrams below, the full three phase is Circuit shown for four stages with all supply and discharge lines, however For the sake of clarity, the series step winding is omitted here, their winding stages to be attached in the usual way on only one leg to need. These are the series step windings C in Fig. I and A in Fig. 2. In these circuit diagrams, too, the supply and discharge lines are again indicated by arrows marked. The individual winding stages themselves are led to terminal boards, where they turn in the usual way by load tray devices at will can be connected to the - supply and discharge lines.

Naturally, it is also possible by omitting each one of the series-stepped windings in Fig. I or 2 to obtain a two-winding transformer in the circuit B / A or B / C from your three-winding transformer with the windings A, B, C. You can now have the same control effect z. B. in the phase direction both by the circuit B1-4 according to Fig. I, in which the excitation device is connected in delta, and by the circuit BIA according to Fig. 2, so with the field winding connected in star. The same applies to the winding which regulates perpendicular to the phase voltage according to the circuits BIC in both figures. In this way you will be independent of the excitation winding circuit that z. B. for compensation purposes in a triangle or to obtain an o-point in a star connection is desired.

Claims (3)

PATENT CLAIMS: i. Three-winding series step transformer for stepwise Adding or dropping voltages. adjustable phase and size by putting them together two perpendicular partial stresses are obtained., characterized in that, that, two induced by a common, arbitrarily switched excitation winding Series step windings are connected so that the step voltage vectors dex one parallel and the other perpendicular to the voltage of the associated network phases get lost. 2. three-winding series step transformer according to claim i, characterized characterized in that with the excitation winding connected in a triangle, the individual stages the series step winding regulating parallel to the phase voltage - two in series each Partial windings exist that; induced by the two phases of the excitation winding connected to the mains phase to be controlled. 3. Three-winding series step transformer according to claim i, characterized in that - b: ex exciter winding connected in star the individual steps of the series step winding that regulates perpendicular to the phase voltage consist of two partial windings connected in series, those of the two Phases: the excitation winding is induced; which are not connected to the - mains phase to be regulated are connected.