DE289164C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

In order to switch off additional transformers, one winding of which is "connected in series with the machine lines, while the other (excitation winding) is connected to the machine voltage or mains voltage, v _N from the mains under current without a current or voltage surge, a method has become known, according to which resistors are first switched in a known manner by a system of switches and switching contacts when the additional transformer is disconnected from the mains between the mains and the excitation winding, whereupon the excitation winding is disconnected from the mains and short-circuited, so that the inductive effect of the additional transformer ceases and then also the winding lying in series in the network can be disconnected from the network after a bypass line has been closed.

In FIG. 1, S denotes the (secondary) winding of the additional transformer connected in series with the network (possibly the induction regulator), P denotes its excitation winding (primary winding), which is connected in parallel with the network. For consideration, it does not matter whether it is a single or multi-phase system. ' In the single-phase system, point O of winding P is connected to the second power line; in the multi-phase system, point O represents the zero point of the excitation winding.

In order to be able to switch off the additional transformer from the mains through the isolating switches II and III, the bypass line must be closed by the switch I beforehand. In doing so, however, care must be taken to ensure that no current or voltage surge occurs, which could have a disruptive effect on the network. For this purpose, according to the known method, the voltage at the excitation winding P is first reduced by switching on the ballast resistor W connected to the power line. This is done by moving the sliding contact K from contact 1 to 4 (in practice it is sufficient to switch on a single resistance stage). The excitation winding is then short-circuited by the transition of the sliding contact to the contact 5 and thus the voltage on the secondary winding S is reduced to a small value. Switch I can now be closed and finally switches II and III can be opened.

However, this method still shows two drawbacks which are practically disruptive. First of all, one end of the series resistor W is connected to the network and may have to be insulated for high voltage. But this makes it relatively expensive. Secondly, the voltage on the secondary winding 5 is still relatively high even if the primary winding P is short-circuited, especially if it is an induction regulator, because the currents flowing in the winding P are induced by force line induction

'are generated in this winding and because of the spatially separated arrangement between the two windings on the stationary and the moving part, there is a large spread them exists. Closing switch I therefore still has a significant impact Current and voltage surge in the wake, which is also in the network, if more sensitive instruments are connected, must make disturbing noticeable.

The present invention now relates to a method for switching additional transformers in which these disadvantages are avoided. According to the present method, the resistor for reducing the voltage on the excitation winding is not connected to the line with which the secondary winding of the additional transformer is in series, but for single-phase current to the earthed return line (possibly directly to earth), for multi-phase current to the zero point leading ends of the field winding of the additional transformer. Then, however, after the voltage has been lowered, the excitation winding is not short-circuited in itself, but rather connected in parallel to the secondary winding in the mains line in such a way that the currents in both windings compensate one another. In this case, the currents flow to both windings from the same network side, but in the inverse proportion of their number of turns, and they are directed in the transformer in such a way that the ampere-turns cancel each other out. Since, in this case, the current flows into the winding P through a line and is not generated by the induction of lines of force, the inductive voltage drop caused by the transformer is the minimum practically attainable. After this parallel connection of the excitation winding with the secondary winding, the bypass line is closed and the isolating switches are opened.

The subject matter of the invention will be explained in more detail with reference to FIG. The meaning of the letters in this case is the same as in Fig. I. As can be seen from Fig. 2, the resistor W, which is connected to the grounded return line in the single-phase network with the point O , or in the multi-phase network between the zero point O and the ends of the field winding leading to the zero point, is only closed for low voltage isolate. According to the method of the present invention, the voltage at the excitation winding "is reduced again by moving the sliding contact K from contacts 1 to 4" through the series resistor W (if necessary, also only in one stage), then winding P and 5 by transition to contact 5 connected in parallel in such a way that the ampere-turns generated by the currents J ₁ and J ₂ compensate each other, the bypass line 1 is then closed by the switch I, and finally the isolating switches II and III are opened.

To switch the additional transformer back on, you can do exactly the opposite be proceeded. In the case of multi-phase systems, the exemplary embodiments shown give only switching on one phase. The figures would therefore correspond to the number of phases to be added accordingly.

Claims (1)

Patent claim: Method for switching additional transformers for single or multi-phase current with secondary winding connected in series with the mains and primary winding parallel to the mains a series resistor is connected in front of the field winding when the additional transformer is disconnected from the mains. whereupon with the appropriate circuit of the excitation winding in series in the network horizontal winding can be disconnected from the mains by a circuit breaker after a bypass line has been closed, thereby characterized in that when the transformer is disconnected from the network, the series resistor for single-phase current at the earth return line, with multi-phase current between the zero point and the ends of the primary winding phases leading to the zero point is switched in front of the primary winding and then under simultaneous When the resistor is completely switched off, the primary winding is connected to the mains in parallel with the secondary winding that the ampere turns generated by the primary and secondary currents in the windings compensate each other, so that the inductive voltage drop of the transformer becomes a minimum, and that finally the bypass line (1) are closed and the isolating switches are opened, which disconnect the transformer from the line, while when the transformer is switched on, the procedure in exactly the opposite order of the individual actions can be exercised. 1 sheet of drawings.