DE630399C - Protective circuit to avoid overvoltages when switching off inductive resistors in electrical circuits with single-pole earthing - Google Patents

Description

When switching off inductive loads, it is necessary to use the inductive Dissipate or destroy the magnetization energy contained in the consumer. To do this It has already been proposed to keep the voltage surges that occur within low limits have been to switch on series resistors first in the circuit of the inductive load, so that one over the Resistances in a short-circuited circuit arise in which the energy runs out. Because the inductance first tries to maintain the current state that existed last, a voltage develops across the resistors, which is equal to the product of the resistances times the pre-existing amperage. So far Single-pole grounding is provided in such circles, arises at the end of the inductance facing away from the grounding point this high voltage, which is a multiple of the operating voltage, which is not the case with completely perfect insulation can easily lead to flashovers. So it was so far required the inductive parts in their winding for a multiple of the operating voltage to isolate. According to the present invention, the highest potential difference between earth and part of the winding is much lower Value be brought that the switched-on series resistor is divided at least into two parts, each of which between an end point of the inductive load and the grounding point.

An embodiment of the invention for the unipolar grounded exciter part of an electrical The machine is shown in FIG. The field winding is designated with ι, with 2 the excitation current source, with 3 to 6 the parts of a multi-stage series resistor, which through normal operation. Switch 7 is bridged. Point 8 is the excitation circuit grounded. Fig. 1 shows the known.

To determine the voltage curve during the shutdown process, in which by. When the switch is opened, the resistors in the exciter circuit are switched on, a voltage diagram is shown in FIG. Here, the 'voltage of the excitation voltage source E _{1 is} entered as the ordinate, the resistance of the excitation winding ^ and the internal resistance of the excitation voltage source r _{2 is} plotted as the abscissa. The line connecting the end points of the abscissa and ordinate represents the geometric location of the voltage differences between the individual points of the circle compared to the grounded point 8, namely for each individual point

^{*) 1} word from de.m patent seeker is indicated as the inventor:

Josef Tittel in Berlin-Lübars,

the associated ordinate up to the intersection of the connecting line is a measure of the voltage difference. The angle α z \ see the connecting line and the abscissa ^ | axis is at the same time a measure for the Stromer "'er' represents the relationship between voltage and resistance.
~ When the additional series resistors are switched on, the current as such is initially maintained due to the effect ίο of the inductance, ie the angle α remains unchanged. As is done in FIG. 3, the diagram can thus be supplemented by plotting the values of the individually switched-on resistors and drawing the voltage line ABFGA again at the same angle α to the abscissa axis. It. the internal resistance of the excitation voltage source r ₂ , then the resistances r _% -r§ of the individual resistance levels and finally the ohmic resistance of the excitation voltage winding r _x again are entered in succession from AA . At the grounded end of the excitation voltage winding, the voltage must be zero, and the voltage line must arrive at the point corresponding to this at the same angle α. It follows that the choke coil, in order to be able to apply the original current to the circuit supplemented by the switched-on resistors, must generate an inductive voltage of the size E _2. Since this voltage is generated distributed over all points of the winding, while on the other hand the ohmic voltage drop in the excitation winding is also distributed evenly over the entire winding, a voltage line FA results in the winding as the resultant of E ₂ and the connecting line GA , which shows the voltage curve represents in the winding. So you can see that starting from the point, the voltage in B first rises to the value of the excitation voltage source E ₁ , from here it gradually decreases as a voltage drop in the individual resistors, passes through a reversal point and then rises further via E up to the Value / ⁷ , which has the greatest voltage difference between the earthed point and the end of the winding facing away from the earthed point. According to the proposal of the invention, part of the series resistor is now placed between the grounding point and the end of the winding facing this, as shown in FIG. The associated voltage curve can again be seen from FIG. 5, from which it can be seen that the highest voltage difference between winding and earth has become considerably smaller

is. By appropriate coordination of the resistors can be achieved that the ,,, both ends of the winding with respect to earth | Jj | the same voltage difference with opposite Have a sign. jif 'So it is possible in this way that the ^ Difference in voltage considerably less keep. So if the winding is still subdivided and between the parts Another resistor part is placed, the voltage difference can be further reduced so that it is easily possible to set any previously determined maximum voltage limit must be adhered to, which, however, entails a certain degree of complexity in the circuit and an increase in the number of switching elements connected is. This is both in the winding itself and in the resistance circuit each time contain a point whose voltage with respect to earth is equal to zero. Because this point with the same resistance distribution is always the same, it is possible to provide this with a connection and its voltage compared to the Constantly compare earth voltage. This way it becomes a very valuable monitoring device gained as any change in the resistances is caused by a shift in the voltage value of this artificial zero point expresses. So it is possible here, for example, a rollover also ... immediately detectable between closely adjacent turns of the windings.

Claims (5)

Patent claims: i. Protective circuit to avoid overvoltages when switching off inductive Resistors in electrical circuits with unipolar earthing, in which to destroy the magnetic energy first switching resistors (short-circuitable resistors) are switched on, characterized in that the ballast resistors are divided into at least two parts, each of which is between an end point of the inductive Resistance and the grounding point. 2. Protection circuit for electrical circuits no according to claim 1 with the supply voltage source switched on, characterized in that that the ballast resistors are distributed on the parts so that the potential of the two ends of the inductive Resistance to earth after switching on the wank resistors the same size but opposite. 3. Arrangement according to claim 2, in particular. for the excitation circuit electrical Machines, characterized in that the individual can be switched off Switching elements assigned to resistance parts are mechanically coupled to one another are. 4. Arrangement according to claim 1 to 3, characterized in that the inductive Resistance is divided into several parts, between which can also be switched off Resistance parts lie. 5. Arrangement according to claim 1 to 4 with once and for all set against to Level gradations, characterized in that the reversal points of the inductive resistances and the series resistors led out and connected to zero voltage monitoring devices are. 1 sheet of drawings