DE649768C - Switching arrangement for the elimination of disruptive influences of higher harmonics of the high voltage voltage on the operation of overlay remote control systems - Google Patents

Description

Switching arrangement to eliminate disruptive influences from higher harmonics the high voltage on the operation of superimposed remote control systems in superimposed remote control systems, in which, for example, a voltage of a non-network frequency for the purpose of remote control is superimposed on the order of a few percent of the heavy current voltage lies, there is a risk that the higher harmonics of the power network Remote control operation is disturbed. In general, one can take action against this danger protect by keeping the frequencies of the superimposed currents sufficiently far from moves away from the frequencies of the higher harmonics, for example in a for the control frequencies used range correspondingly large gaps for the network harmonics releases. This protection fails, however, if the higher harmonics of the network, for example through = resonance phenomena on long high-voltage lines or 'Other causes are amplified beyond normal levels. -Just in recent times, in which there is more and more going on to use widely spaced consumer and connecting production areas by pipelines, there is a risk of that because of the great extent of the sometimes multiple meshed overhead lines and cable sections of composite conductor structure at individual points on the pipeline especially the higher harmonics, preferably at times of low load develop strongly or the higher harmonic caused by a defective or inadequate Consumer or producer caused excessive strength at one point of the network . be carried to other power supplies.

The invention has the task of eliminating such disturbances for the remote control operation to exclude. It assumes that, as a rule, such remote control systems not an entire overland network with all producers and consumers, but only relatively narrowly defined urban or rural districts are remotely controlled, . and mostly for the reason that different areas are inherently different for the individual sub-areas Considerations for the remote control are decisive. Often that is limited Overlay on pure consumer areas, in particular on medium-voltage or Low-voltage networks, in which experience has shown the formation of higher harmonics is not favored per se.

According to the invention, the network to be overlaid becomes in the case of series overlay against the Voltage source of the higher harmonics through for the bridging circuits permeable to higher harmonics, with parallel superposition through those in the line that are difficult to pass through for the higher harmonics Trap circuits separated.

The invention will be explained in more detail with reference to the circuit diagrams.

In Fig. I i is a high-voltage transmission line, the voltage of which is through the transformer 2 for the network 3 to be superimposed is reduced. :1. is the Overlay generator that works in series. For this purpose, in the train of each conductor switched on a transformer 5, its secondary winding is bridged by a capacitor 6. The inductance of the transformer 5 is, together with the capacitance of the capacitor 6, to the respective superimposition frequency Voted. Between the superposition point and the transformer 2 are for the higher harmonics permeable bridging circuits 7 between the network conductors switched on, the series connection of an inductor g and a capacitor 8 exist. These two parts are on resonance for the frequency of the main occurring higher harmonics, so for example in three-phase networks with 5o Hz to 25o Hz. In the event that other harmonics of the mains voltage are also used Should occur to a greater extent, there can be several on the individual harmonics Matched Durclasskreise used; -ground, or it can be mixed by appropriately Circuits of inductances and capacitances a line circuit can be created. which lets the various harmonics through.

A particular advantage of this circuit is that the interfering higher harmonics partly in interaction with the leakage inductance of the transformer2, partly in cooperation with the locking devices 5, 6 are suppressed sufficiently strong and that at the same time the series superimposition is favored because the C bypass circuits 7 otherwise through the transformer 2 Reduce the conditional resistance for the superimposed control currents.

The transformer 2 is not a necessary part of the pinned circuit. Instead, any other leakage reactance, e.g. B. a choke coil or the reactance of the network i. It is only necessary that the network i or the connection line between your network i and network 3 is zero has different resistance or reactance.

To explain the interaction of the individual circuit parts in more detail, reference is made to FIG. The following assumptions are made: a) The performance of the network i is large compared to that of the superimposed network section 3, so that the network resistance can be neglected by i as a first approximation, b) network resistance of the superimposed Section 3 = 100 ohms, c) disruptive network harmonics in the network i 250 Hz, 100 volts, d) Superimposed control frequency for the Fetz 3-275 Hz, 100 volts.

On the basis of assumption a, the given type of overlay for network section 3 is a series overlay, as shown in FIG. The following relationships apply for a single-phase approach: i. Is the superposition current to be superimposed network section 3 in series with the i virtually short-circuited through the power transformer 2. The transformer 2 provides the superimposition current a resistance which is practically equal to its leakage reactance for 275 Hz. For conventional transformers of this resistor is about 30 ohms be. The network 3 has ioo ohni, the @esaint resistance for the n superimposed current is: 1-'ioo2- + 3 & = - io4. Ohm. The network 3 is assumed to be purely ohmic, and the leakage reactance is assumed to be purely inductive.

2. In order to, the network 3 has a superposition voltage of, for example To bring 100 volts, the tone generator must: I because of the upstream of the mains Stray reactance of the transformer 2 has a slightly higher voltage, namely io-. Volt, hand over.

3. The network harmonics of 250 Hz, 100 volts present in network i are to be prevented from penetrating network section 3. In principle, this could be done by blocking circuits tuned to 250 Hz, as shown in FIG. 3, or by control circuits in FIG. The essential finding of the invention is that only guide circles can be considered for the series superimposition according to FIG. The reasons are as follows: q .. In order to weaken the interfering harmonic from 25o Hz to 1 / 1o of its value in network i, a blocking circuit resistance of goo ohms would be necessary. Then with a resistance of the network 3 of iooOhm a total resistance of goo +. ioo = iooo ohms would be available for the harmonic, and the voltage of the harmonic would remain at 8 / 1o on the blocking resistor and only% o would come into network 3. This would be sufficient to lock out the harmonics, but this results in considerable disadvantages for the superposition with 275 Hz. The superimposed current must now also overcome the resistance of the blocking circuit connected upstream of the transformer 2. A blocking circuit for 25o Hz even in a very good design with a blocking resistance of goo ohms at 250 Hz will still have a resistance of about i5o ohms at 275 Hz. These 150 ohms are additionally connected upstream of the network 3 and require a significantly higher voltage and thus the power of the tone generator 4 to overcome them.

5. The situation is fundamentally different if in this case, as shown in Fig. I, control circuits tuned to 25o Hz are used to suppress the network harmonics. For the network harmonics, the circles represent a load resistance, which is preceded by the leakage reactance of the transformer 2. If this reactance is 30 ohms for 25o Hz, it can be assumed to be around 27 ohms for 275 Hz (see section i). If the control circuit resistance is chosen to be 3 ohms, the voltage of the harmonics is also split up in this case, with 9 / 1o remaining due to the leakage reactance of transformer 2, while only 1 / 1o comes to the control circuit and thus to network 3 . It is particularly advantageous that the ratio of this voltage distribution is practically independent of the size of the network resistance 3, that is, independent of the size of the load on this network, which would also not be the case if blocking circuits were used.

In contrast to the blocking circuits, the control circuits do not only make it difficult for the superposition, but even make it easier, because they are parallel to the transformer 2 and thus reduce the resistance of the return circuit for the superposition current. A control circuit with a resistance of 3 ohms for 25o Hz will have a resistance of about 18 ohms at 275 Hz, which are parallel to the leakage reactance of transformer 2, so that the total resistance of the return circuit is only about 10 ohms instead of 30 ohms without control circuits will. The voltage at the tone generator can even be a little lower than mentioned in section 2, while the network harmonic is still safely locked out. The advantage of the circuit is thus proven.

The presence of the transformer 2 is not an absolute prerequisite. it just makes it easier to visualize. If the transformer is missing, go to the Place the Strett reactance of this transformer, the real and reactive resistances of the Line i, which may require a different dimensioning of the control circuit, but basically the same effect as the leakage reactance of the transformer have, namely that with the correct dimensioning of the control circuit resistance the greatest Part of the voltage that network harmonics remain on them.

Fig. 2 shows essentially the same arrangement, only here is in the bridging circuits 7 instead of a series connection of the inductance and Capacitance uses a parallel connection based on: the power frequency of the Network is coordinated and, as the left side of the figure shows, under certain circumstances can be coupled transformeriseh. Such a circuit is for heavy current almost impermeable, but forms a capacitive one for the higher harmonics Short circuit, so it also bridges the inductive resistance of the transformer at the same time 2 for the control currents.

In Fi: g. 3, the transmitter 4 operates with parallel superimposition, i. H. he is connected between the conductors of network 3 via press-on circuits. The pressure circles consist of the series connection of an inductance and a capacitance, respectively is matched to the superposition frequency. The layered network is through for the higher harmonics heavy: permeable trap circuits i i from the transformer 2 separated. The trap circuits, which, as indicated in Fig. 3, transform into the cable run can be coupled., consist of the parallel connection of a Inductance and a capacitance based on the frequency of the main harmonic is matched. If more harmonics need to be suppressed, more trap circuits can be used be used, which are tuned to the individual harmonics, or it can Mixing circuits of inductances and capacitances are used for the individual higher harmonics are impermeable.

This circuit, too, not only provides sufficient suppression disturbing harmonics, but it also has a beneficial effect on the superimposition operation from when the blocking circuits i i also a migration of the control energy via the transformer 2 in the network i complicate. Favorable on the suppression of the higher harmonics The pressure circles also have an effect, since these even when the network is idling 3 practically bridging paths for e.g. Find proportions of the higher harmonics.

If one assumes, based on the numerical example in FIG. I, the resistance of the transformer 2 in FIG. 3 at 25o Hz as 27 ohms, oei 275 Hz as 30 ohms, the resistance of the trap circuits ii at 25o Hz as goo ohms, at 275 Hz to 1.50 ohms, the resistance of the conducting circuits io at 25o Hz to 18 olim, at 275 Hz to 3 olim and the resistance of the network 3 to 100 ohms, while the resistance of the network i is neglected, then of the 100 volts the higher uronics with 25o Hz in the presence of the conductive circuits io on the network 3 about 11192, this voltage, since the resistance of the network 3 is reduced from 100 olim by the parallel connection of the conductive circuits io with i8 ohms to 15 olim. If the control circuits 10 were not present, then the network 3 would have an approximately ten times larger portion of the voltage of a 50 Hz.

If the trap circuits ii were not present, the superimposing currents generated by the generator 4 would be distributed over the network 3 at a ratio of about 100: 3o at 275 Hz, i.e. 1i. more than = / 3 of the superimposition energy would migrate into the network i. If, on the other hand, the blocking circuits ii are present, as in FIG. 3, the superimposition current is distributed in the ratio ioo: iugo to the networks i and 3, ie the network 3 now receives significantly more superimposed energy than if the blocking circuits ii were not present.

In Fig. Q. the trap circuits i i exist, which are also transformer-based here are coupled into the cable runs, from the series connection of an inductance and a capacity that is matched to the power frequency of the network. the Trap circuits therefore have practically no resistance to the mains current, they work but strongly throttling for currents of higher frequency. Also with this circuit results the same favorable between the blocking circuits i i and the compression circuits io Interaction as in Fig. 3.

It is recommended to use the blocking circuits i i or the bridging circuits 7 to be connected on the side of the transformer 2 facing the transmitter, so that the transformer is capable of generating a sintis-shaped voltage wave any higher harmonics of the magnetizing current required refer to your high-voltage network i.

Claims (1)

PATENT APPLICATION IE: i. Switching arrangement for elimination disturbing influences from higher harmonic niches of high voltage on the Operation of overlay remote control gen with the help of guidance or Trap circuits, characterized in that in the case of series overlay, on the one hand, the for the higher harmonics permeable bridging circles (7, Fig. I), between the voltage source (a) of the higher harmonics and your network to be overlaid (3) are switched and to suppress the serve higher harmonics through the series consisting of blocking circuits (5, 6) press-on device supported, other- on the one hand by the bridging circles (7) for the higher harmonics of the stand of the overlay channels (2 and 3) is reduced. Arrangement to eliminate disruptive Influences from higher harmonics of the Heavy voltage on the operation of Overlay remote control systems under additional the help of control or blocking circles, characterized in that with parallel superposition on the one hand the effect of the in the line between the voltage source of the higher harmonics and the network to be superimposed (3, Fig. 3) the blocking circuits (ii), which are the higher Suppress harmonics through the imprints consisting of guide circles (to) device is supported, on the other hand the migration of the overlay stream into the not to be superimposed Power supply unit (i) through the blocking circuits (ii) difficult for the higher harmonics will.