DE1100156B - De-excitation device for synchronous generators - Google Patents

Description

De-excitation device for synchronous generators For fast de-excitation Several methods of synchronous generators are known. With the simplest and With the oldest type of de-excitation, resistance de-excitation, resistors are more suitable Size placed in the inductor circuit and in the field circuit of the exciter, whereby the time constant of these circles is greatly reduced and thus a rapid decay of the magnetic field is made possible. It is in the nature of this circuit that the voltage occurring on the slip rings is relatively high and too leads to uncomfortable insulation stress on the winding. With large generators the achievable de-excitation times are also unsatisfactory.

The oscillation de-excitation indicated by Rüdenberg brought about both points a significant advance. The basic idea of this procedure is to by negative excitation of the main exciter with the help of the inductor slip rings occurring self-induction voltage to force a polarity reversal of the inductor current. With such a counter-excitation one achieves a very rapid degradation of the magnetic Flux in the generator because the polarity reversed inductor current is pushed into the damper cage positive flow largely compensated. It is easy to see that the The faster the inductor current of, the faster the generator voltage comes to zero its positive value at the beginning of the de-excitation comes to a negative value and the more negative it becomes. However, there are limits to this endeavor, that the structure "inductor winding - oscillation resistance - main exciter - main exciter field" is capable of oscillation, d. That is, the electrical processes that take place in this mistaken identity do not come to an end when the generator voltage has become zero, but rather If the setting is unsuitable, the arrangement can cause undamped oscillations, d. In other words, the generator voltage returns after the first zero crossing, increases to a maximum value, decays again; this game can play any number of times repeat.

Without additional damping devices, this disadvantage can only be avoided avoid that the counter-excitation of the main exciter caused by the slip ring tension with the help of a series resistor is throttled so far that the entire de-excitation process is sufficiently subdued. But it is obvious that such a throttling the counter-excitation leads to an extended de-excitation time. In an improved Switching the oscillation de-excitation one encounters the disadvantage of the longer de-excitation time in that a very small damping is set at the beginning of the de-excitation, d. H. a very strong counter-excitation is generated and after a certain time when the Generator voltage has largely subsided, the attenuation is greatly increased, so that a slow run-out of all electrical quantities is made possible. The enlarged Attenuation is z. B. either made with a timing relay or with a sensitive one Relay arrangement that monitors the generator voltage or the generator current. That The time relay is activated at the same time as the de-excitation switch is triggered; but it has a fixed time setting, and for this reason only one is very successful unsatisfactory adaptation to the de-excitation process, because the electrical conditions are are very different in the de-excitation, whether the generator z. B. from idle or is to be de-excited from the short circuit. Therefore a switching device is that monitors the generator voltage or the generator current, much more adaptable. Such additional devices make the entire circuit essential in any case more complicated and more prone to failure.

A de-excitation circuit is also known in which the auxiliary exciter except for a field winding fed by the slip ring voltage of the synchronous generator has another field winding that is removed from the inductor current during the de-excitation process itself is traversed. That generated by this field winding, of size and direction of the inductor current dependent excitation component should be used in conjunction with the Slip ring voltage determined excitation component an aperiodic decay of the Purpose of generator excitation current. The furnishing is, however, quite unusual Training of the auxiliary exciter machine is very complex.

The invention relates to one based on the principle of vibration de-excitation working de-excitation device for one excited about slip rings Synchronous generator with a main exciter whose field = winding in the de-excitation case with one of the polarity reversal of the main exciter, from the slip ring voltage caused exciter component and with an additional polarity reversal of the main exciter supporting excitation component proportional to the generator excitation current will. According to the invention, the device is made so that the generator excitation current proportional excitation component in the area of negative generator excitation current cancels the excitation component stemming from the slip ring voltage. Basically the counter-excitation proportional to the slip ring voltage becomes the inductor current proportional share superimposed, so that on the one hand by the strong counter-excitation of the main exciter, depending on the slip ring tension, a very fast one De-excitation of the generator is achieved, but on the other hand by lifting this Influence in the second phase of the de-excitation process after the zero crossing of the Inductor current the occurrence of undamped oscillations is avoided. For the The excitation component proportional to the inductor current is only an ohmic series resistor is required, which is made with the help of a contact on the de-excitation switch between the field winding the main exciter and the oscillating resistor in the inductor circuit is switched. In terms of control technology, this branch of current represents a return that despite small attenuation of the inductor winding, oscillation resistance, main exciter and main exciter field existing main circle a rapid decay of the oscillation in the second phase of the elimination process with a negative inductor current.

In Fig. 1 of the drawing, an embodiment of the invention is shown schematically. The synchronous generator 1 has an excitation winding 2, the end points or slip rings of which are designated by 21, 22. There is also a main exciter 3 with a field winding 4 and an auxiliary exciter 5 with an unmarked field winding. As usual, the oscillating resistor 6, to which the de-excitation switch 7 is connected in parallel, is located in the inductor circuit. The de-excitation switch has contacts 71, 72, 73, which are closed when the de-excitation switch 7 is open, and a contact 74 in the excitation circuit of the main exciter. The field winding 4 of the main exciter can, as can be seen from the circuit, be connected to the slip rings 21, 22 via the contacts 71, 72 or a series resistor 9. A field regulator B is located in the excitation circuit of the main exciter. There is also a circuit through which the voltage drop at the ends of the oscillating resistor 6 is detected. This circuit contains, among other things, the contact 73 and the ohmic resistor 10, which will be discussed later.

In normal operation, the oscillating resistor 6 is from the de-excitation switch 7 bridged. His contact 74 is closed, so that the field winding 4 from the Auxiliary exciter 5 is fed via the field controller 8. Contacts 71, 72, 73 of the de-excitation switch are open.

The sequence of a de-excitation process is described below using the graph in FIG. This shows the generator voltage Uc, the course of which coincides with that of the main flux 0. Furthermore, the excitation or inductor current Je is shown, the slip ring voltage US, the self-induction voltage UL and the resulting flux D.

The de-excitation process is initiated at time to by opening of the de-excitation switch 7, at the same time its contact 74 is opened, so that the field winding 4 is no longer under the influence of the voltage of the auxiliary exciter 5 stands. At the same time, the contacts 71, 72, 73 are closed.

By opening the de-energization switch 7, the bridging is of the oscillating resistor 6 canceled, and the inductor current Je must now be Take way over this resistance. The increase in resistance of the external circuit the inductor winding 2 responds with a self-induced voltage UL or grinding ring stress US, the level of which depends on the magnitude of the oscillation resistance, along with other influences 6 depends. While the inductor used to be an energy consumer, it is now through the reduction of the magnetic field energy, which is converted into heat in the oscillating resistor 6 becomes, to the energy source, which tries to the inductor current I, still further in the previous one Maintain direction. The voltage US on the slip rings 21, 22 therefore has their polarity also changed. This self-induced voltage occurring at the slip rings reverse polarity is via the contacts 71, 72 and the series resistor 9 of the Field winding 4 of the main exciter 3 pressed, in such a sense, that this also reverses its original tension direction. The main exciter 3 now supports the current-weakening effect of the oscillating resistor 6, the Inductor current 1e therefore decays fairly quickly, becomes zero at time ti and then increases to a level that is essentially dependent on the size of the series resistor 9 negative value. As a result, the inductor current lifts the one that is pushed into the damper cage polarized flooding to a large extent.

If now both the flow through the inductor winding 2 and the The flooding of the damper cage would decay in the same time behavior, an ideal aperiodic decay of the generator voltage to zero would be achieved. But this is not the case because the two throughflows are completely different Are exposed to influencing factors. The damper flow sounds similar to an e-function from, but the flow through the inductor winding essentially depends on the voltage of the main exciter, which in turn feeds the excitation from the to the Slip rings 21, 22 occurring self-induced voltage UL or slip ring voltage US receives. This excitation therefore continues as long as the generator flux is 0, i.e. H. even the generator voltage UG decreases. The decay curve of the generator voltage is running but because of the negative inductor current, it tends towards zero rather steeply, so that too at time t2, in which the generator voltage UG has reached the value zero, still a fairly high slip ring voltage US and thus a correspondingly high one Counter-excitation of the main exciter3 exists. So there is still a considerable flow negative inductor current 1e, while the damper flow rate D at this point in time has already completely or almost completely subsided. The consequence of this is a negative one resulting flooding and a recurring generator voltage.

This drawback is eliminated according to the invention when the Excitation of the main exciter caused by slip ring voltage US in good time so is reduced that damper flow and flow of the The inductor winding fades away approximately evenly. This is the purpose of the circuit with the ohmic resistance 10. The influence of this resistance is best seen, if one considers the current distribution during the de-excitation process. The over the series resistor 9 of the field winding 4 of the main exciter supplied current portion It practically stays in the same direction during the entire de-excitation process at, since the voltage on the slip rings 21, 22 of the flux change in the generator and thus the decrease in generator voltage is also proportional. This share of electricity In the field winding 4, a current component i2 is superimposed via the ohmic resistance 10. This current component is caused by the voltage drop at the ends of the oscillating resistor 6. This current component accordingly changes with the inductor current its polarity. During the first phase of the de-excitation process, as long as the inductor current is still positive, the current components il + i2 support each other. From the moment in which the inductor current Je becomes negative, however, the current component i2 acts on the current component il, which takes care of the counter-excitation, and in this way slows down the counter-excitation in time and automatically.

For the construction of the device it is important that in addition to the de-excitation switch and some of the contacts belonging to it, no mechanically moving parts are necessary are. In the present case, only the ohmic resistor 10 is required for coordination, which can be easily adjusted. The mutual influence of the two over the field winding 4 guided circuits can be determined by a suitable choice of the ohmic values the resistors 9 and 10 keep within such limits that the effectiveness of the arrangement is not affected. Because of its simplicity, the circuit offers the highest possible level in terms of operational safety and allows a very short de-excitation time to be set in spite of this.

Claims (4)

PATENT CLAIMS: 1. Working according to the principle of vibration de-excitation De-excitation device for a synchronous generator excited via slip rings a main exciter whose field winding in the de-excitation case with a die Reversing the polarity of the main exciter caused by the slip ring voltage Exciter component and with an additional one, the polarity reversal of the main exciter supporting excitation component proportional to the generator excitation current is characterized in that the excitation component proportional to the generator excitation current in the area of negative generator excitation current, those resulting from the slip ring voltage Excitation component cancels. 2. De-excitation device according to claim 1, characterized in that that over the field winding (4) of the main exciter (3) two circuits are conducted are one of the slip ring voltage, the other of the voltage drop is fed at the de-excitation resistor (6). 3. De-excitation device according to claim 1 and 2, characterized in that the one circuit of the generator slip rings (21, 22) via contacts (71, 72) of the de-excitation switch and a series resistor (9) runs to the field winding (4) of the main exciter. 4. De-excitation device according to Claim 1 to 3, characterized in that the other circuit runs from the terminals of the de-excitation resistor (6) via contacts (71, 73) to the field winding (4) of the main exciter and contains an ohmic resistor (10). Considered publication: German Patent No. 527 039; Austrian patents No. 172 867, 172883.