DE2854092C2 - - Google Patents

Description

The invention relates to a method for switching off an inductive Load in a three-phase high-voltage network using a Switch with short dielectric recovery time.

It has been shown that when switching off an inductive load in a three-phase high-voltage circuit on the one to be switched off Sometimes high surge voltages occur. Because this overvoltage conditions due to insulation breakdown or the like There can be numerous damage to the circuit Investigations were carried out to determine the probable causes to determine this high overvoltage. Have these investigations show that the high overvoltages only occur when in the circuit in question at least one of a number of Be conditions met, the most important of which are listed below are:

• 1. Switches should be used for switching, their dielectri cum recovered quickly; this condition is through vacuum scarf ter met.
• 2. The requirement of predetermined circuit design; here among other things, the existence of a sufficient Capacity between phases on both the generator side and  also on the load side of the switch.
• 3. The switching time should be selected so that shortly after the Disconnect the contact elements at one pole of the switch Current zero crossing occurs.

When a load is switched off under the above conditions, an overvoltage occurs in the first phase, which is interrupted when the current passes zero, which can result in a re-ignition in this phase. Under the prevailing circumstances, the current caused by these flashbacks, which is very high-frequency, is wholly or partly superimposed by the mains current in the other phases, which still carry current despite an interruption that has already taken place. If the current resulting from this superimposition and the circuit current flowing in these phases becomes approximately zero, then the other two phases are also interrupted. However, since at the moment of re-ignition, the circuit current in the first phase that caused the re-ignition is close to zero current, the instantaneous value of the current in the other two phases is relatively high and so-called high current chopping occurs. In the literature, this phenomenon of the relatively high current occurring in pulses is generally referred to as virtual chopping. Since the current increase d i / d t is high, very high overvoltages can occur in the system.

The overvoltages that occur when inductive currents are switched off tensions and the associated difficulties are in known to the experts for some time and in a variety have been discussed by publications. In the essay by A. F. B. Young "Some Researches On Current Chopping In High-Voltage Circuit Breakers "in The Proceedings of the Institution of Electrical Engineers, No, 76, August 1953, pages 337-353 the mechanism of arc extinguishing in high voltage network switches discussed. There it is stated that this effect depends on a variety of parameters and by the own shafts of the switch, for. B. influenced by its capacity is. In the essay by J. Panek and K. G. Fehrle "Overvoltage Phenomena Associated With Virtual Current Chopping In Three Phase Circuits ", IEEE Transactions on Power Apparatus and Systems, July / August 1975, pages 1317-1325 as well in the publication by M. Murano et al "Three phase simultaneous interruption in interrupting inductive current using vacuum switches "in IEEE Transactions on Power Apparatus Systems "January / February 1974, pages 272-280 the effect of the "Virtual chopping" and described as a protective circuit in series with a capacity parallel to the load between the Phase and ground switched resistance proposed. A such protection circuit is also in the publication by M. Murano et al "Voltage Escalation in Interrupting Inductive Current By Vaccum Switches "in the same journal, pages 264-271 as an effective protection circuit to prevent voltage suggested.  

Another, proposed in the mentioned publication NEN method, a non-linear resistor is used, the high costs are also disadvantageous.

According to a further method, surge arresters are used for Limiting the harmful effects of "virtual chopping" used. This method also has the relative disadvantage high cost, and besides, these surge arresters must do so be installed as close as possible to the load.

The above-mentioned methods have in common that they are only under operate the circuit conditions for which it was designed are. If you change these conditions, you have to Modify procedure according to this change. Furthermore are these procedures are not against the prevention of "virtual chopping" directed, but only to protect against its effects.

A better method would therefore be to "virtual chopping" full to avoid constantly. This can be achieved if you go for it ensures that one of the above three conditions for this Occurrences are not fulfilled.

When considering the special advantages of a vacuum switch wishes to use, then the first condition must be met. To switch off the second condition, both the current source-side as well as the load-side supply lines of the scarf be completely shielded from each other. In practice however, this appears to be a difficult and expensive task.

Finally, the third condition must be prevented from occurring are achieved by synchronizing the switching time with the zero current continuity such that the contact elements are not close to the current zero crossing can be separated. But also such measures ver long use of complicated and expensive facilities.

The object of the invention is now to provide a switching Method for preventing "virtual chopping" on simple  and accordingly less expensive type regardless of the Circuit conditions.

The invention therefore provides a Schaltver drive of the type mentioned above, which is characterized by it net that after the break two of the three switching paths that have a short dielectric recovery time by at least a third a period of line frequency later than the first switch gap open plus the minimum spark time in the first Switch range.

This switching method guarantees that under no circumstances some "virtual chopping" is possible anymore.

The invention also provides a switching mechanism which in is able to prevent "virtual chopping". That scarf Term mechanism is characterized by means, which in the sub break initiate the opening of a switch route earlier than for the other two switch routes, in such a way that between the time at which the first switch route is opened and the time at which the other two switch routes be opened, an interval that is at least a third corresponds to the period of the mains frequency.

The invention will now be described in more detail with reference to Drawing explained. It shows

FIG. 1 is a simplified circuit diagram for explaining the switching process;

Fig. 2 is an illustration of the time course of the currents for illustrating the operation when the current is interrupted in the corresponding phase at the next current zero crossing when opening a switch link or a pole; and

Fig. 3 is a representation of the case in which when the switch path or the pole is opened, the current in the phase concerned is not interrupted at the next current zero crossing.

In Fig. 1, the switch or the load are indicated by the reference numerals K and L , the phases designated R, S and T and the associated switch paths of the switch with the reference numerals 1, 2 and 3 respectively.

It is now assumed that the switch path 1 of the phase R opens earlier than the switch paths 2 and 3 of the phases S and T , that is to say with an interval T ₂ which is equal to or greater than one third of the cycle of the mains frequency increased by the minimum arc duration of the switch with power line up to "virtual chopping".

In FIG. 2, a limiting case is shown where the "virtual chopping" can occur, that is, a situation in which the opening time t ₁ corresponding to the opening of the switches route 1 is selected so that, between this point t ₁ and the next current zero crossing at time t ₂ of phase R the interval T _{1 is} provided, which is equal to the minimum arc duration of the switch. The scarf routes 2 and 3 of phases S and T are opened at the time t ₃ ge, and between the times t ₃ and t ₁ is the aforementioned interval T ₂ .

You can now imagine two situations, namely

• a) the situation shown in FIG. 2, in which the current in phase R is interrupted at the first current zero crossing after the switch path 1 has been opened, that is to say at time t ₂ ,
• b) the situation corresponding to FIG. 3, in which the current in phase R to the first current zero crossing after opening switch path 1 is not interrupted.

In situation a) no "virtual chopping" can occur because at time t ₃ the other switch sections 2 and 3 of phases S and T are still closed and accordingly one of the conditions for "virtual chopping" is not fulfilled, namely a simultaneous three-phase switching. After opening the scarf stretch 2 and 3 at time t ₃ , the currents in these phases are interrupted simultaneously in a known manner, for example at time t ₄ . If the opening time t _{1 of} the switch path 1 is brought forward to an earlier point in time, that is, if the interval between t ₁ and t ₂ extends beyond the interval T ₁ , then the current in phase R is certainly interrupted at point in time t ₂ , because the arc duration of the switch path 1 is longer than the minimum arc duration T _{1 of} the switch, so that "virtual chopping" seems impossible even in these cases.

However, if, according to case b), the current in phase R is not interrupted at time t ₂ , then this current is only interrupted at the next current zero crossing, ie at time t ₄ , as shown in FIG. 3. The other switch sections 2 and 3 are then opened at time t ₃ , so that the switch section 2 opens just after the current zero crossing of the phase S in question. Accordingly, phases S and T are only interrupted in a known manner at the time t ₅ . If the power interruption in phase R takes place in the manner described at time t ₄ , then no "virtual chopping" occurs because at this time the separation of the contact elements of the switch route 1 has taken a sufficiently long time to prevent reignition. If the opening time t _{1 of} the switch path 1 is delayed ver, i.e. if the interval between t ₁ and t ₄ becomes smaller, then the switch path R is always interrupted at time t ₄ until this interval becomes so short that the under a) discussed case occurs again. It is obvious that in case a), after setting time t ₁ to an increasingly earlier time, this case a) changes to case b). Where the cases a) and b) mark the boundaries of the area "routing" to "virtual chopping", the switching method according to the above explanations prevents the phenomenon of "virtual chopping".

In summary, it should be noted that in all of the above Falls the current in the switch range first opened first is interrupted at a time when either the at the other switch routes are still closed or the first  open switch route is already open so far that a "Virtual chopping" can no longer occur. Indeed Of course, the situations described above also exist, if one of the other two switch routes is opened first, whereas the result of the switching process is also independent of is the phase sequence of the three-phase power network.

The invention thus creates a switching method which contributes to this carries that you can switch under different conditions without that a "virtual chopping" occurs and without any particular measure besides the simple adjustment of the switch would be necessary. In practice, this switching method can be used by Ab conversion of the switch mechanism of the switch in such a way that when opening a switch route earlier than the mentioned time than the other two switch routes open. It is self-evident of course that switching on in the normal way at the same time for all three switch routes are carried out. A common mechanism that works well suitable for the switching method according to the invention is in the Netherlands Described patent application 76 06 848. That mecha nism only needs to be modified so that the cams, which control the switching on and off, two switch sections Press simultaneously while the third switch route through a separate or offset cam disc operated separately becomes. This separate cam disc can be designed that the associated switch route with their help around the ge desired time before opening the other two switch routes is interrupted. Switching on can remain unchanged.

Claims (2)

1. A method for switching off an inductive load in a three-phase high-voltage network with the aid of a switch short dielectric recovery time, in particular vacuum switch, characterized in that after the interruption two of the three switch paths short dielectric recovery time open at least a third of a cycle of the mains frequency later than the first switch path plus the minimum arc duration in the first switch path. 2. Switch for switching off an inductive load in one Three-phase high-voltage network with a mechanism that one switch distance shorter for each of the three phases Dielectric recovery time, especially vacuum switch path, has, characterized by means which in the sub break opening a switch route earlier than for the other two switch routes in such a way initiates that between the time the first switch route is opened and the time to which the other two switch routes opened be an interval that is at least a third one cycle corresponds to the operating frequency of the network plus the minimum arc duration of the first Switch range.