DE408370C - Chained multi-phase power transmission system - Google Patents

Description

Chained multiphase power transmission system. The invention relates to an interlinked multi-phase power transmission system which is unsymmetrical due to its design and aims at such asymmetries, which are not in a possible asymmetrical Usage load, for example, by the consumer, but rather in the training of the Systems themselves have their own cause, to be eliminated by simple means. Such Asymmetries can be caused by a simplified circuit used for Simplification and cheapening of the machines and equipment required or applied which is carried out to simplify the power transmission line. In particular can aim at such a simplified line design, a phase of a Replace the polyphase system in whole or in part by earth or a weak or Do not use an insulated cable for this phase, which is made of a different material (e.g. iron) than the other lines (e.g. copper). On the other hand you can but also asymmetries of the power transmission system between. Supply and acceptance circuit or circles, apart from the asymmetrical one which is not considered here Usage load, which is caused by the fact that during the execution and laying of the Lines between supply and acceptance circuit unavoidable manufacturing and assembly inaccuracies occur which can be described as unintentional and which can also be caused by twisting the lines could not be completely eliminated so far.

The invention is that the tensions of such chained and between supply and acceptance circuit or circuits from any the specified causes of asymmetrical multi-phase power transmission system thereby be balanced to any extent that active or reactive current or both consuming Devices of variable or unchangeable resistance, directly or indirectly connected between the interlinking point and one or some of the phases of the system will. Likewise, the same devices can also be between two or more Chaining points of phase groups are switched on. The currents of such Systems are also powered by active and reactive current or by active or reactive current consuming devices symmetrized to any degree, which are indirect or can be switched directly between individual phases of the system.

The invention makes it possible in particular to use machines, transformers and similar apparatus with simplified winding and iron construction in practice to use, but also to run AC power lines where a phase through earth, a bare or poorly insulated line or a such a different cross-section and different material than the remaining lines are formed will. Furthermore, one can also use single-phase systems with center conductors, which are similar Way, as described above, are designed asymmetrically, in practice without having to accept asymmetrical shifts in currents and voltages to have to.

The invention therefore differs fundamentally from the known Versions that primarily compensate for the Payload of the system had in mind, without considering whether the system in "itself, that is for example, when the useful load is switched off, is also balanced. Asymmetries the voltage can, for example in a short-circuit test, asymmetries of the currents Determine (no-load currents) when the network is idle - if there are any are - with regard to tensions, the greater the degree, the further one goes into the Investigation, starting z. B. from. the low-voltage side of the power plant transformer, away from the power plant (the supply circuit), or with regard to the currents, depending the closer you get to the power plant. Such asymmetries are found here, the invention thus intervenes and the devices described at the outset succeed for use, namely the balancing takes place in such a way that the natural electrical properties of the individual phases (ohmic or capacitive or inductive ZViderstand) can be artificially changed relative to one another to such an extent that the desired degree of symmetry is achieved. So you could for example at a three-phase system with asymmetrical partial capacities the capacitive symmetry by connecting inductances in parallel to the larger (natural) capacitances or by connecting artificial capacities in parallel with the smaller natural ones Creating capacities in contrast to the known method, capacity effects by connecting inductances in parallel according to the principle of current resonance eliminate .. While by this latter measure the lines from the capacitive Charging current are to be relieved, the present invention seeks only equalization of the charging currents in the individual phases, which may even increase the Phase current compared to the previously existing asymmetrical condition can.

In principle, the invention encompasses all known types of installation options for the specified resistances. For example, you can use the voltage or current balancing resistors Use alone or at the same time, in different or in the same place or build in places, they can be carried out separately from each other or as one unite common apparatus: It is the same in principle for the idea of the invention it does not matter whether the device mentioned. directly in the to be compensated Part of the system can be switched on or whether this is done directly with the help of magnetic or capacitive clutches according to known switching methods.

We want to limit ourselves to the numerous switching options to describe in more detail a case of three-phase current transmission according to the principle given.

In Fig. I, a means a normal three-phase generator. Its tension is transformed into two single-phase transformers c and d using the known V connection. The interlinking point is earthed on the high voltage side, both at Beginning as at the end of the long-distance transmission; there is a special return line in this So fall unnecessary. The burden in the end may consist of three equal _ large f4 resistors connected in star, so that the power factor in all three Phases at the end of the line practically = i. Let us further assume that above the overhead line pylons an earth wire was laid, which had a different cross-section and for this reason, as well as due to the grounding, also other resistance constants like the other two insulated lines, this is what you get in Fig. 3 shown capacitive scheme of the pipeline, from which the distribution of the Charging currents results. For the sake of simplicity may equality between the following Capacity values are assumed: k02 = k, 3 and k12 = k13.

It is readily apparent that the "return line" exists made of earth and earth wire, carries a larger charging current than either of the two isolated ones Cables. The symmetry of the charging currents in the three lines, both according to Both size and direction can now be established either by the capacity k23 increased by placing between phases 2 and 3 directly or indirectly a (capacitive) reactive load switches, or by changing the capacitance values k02 and k03 are reduced accordingly by placing directly or indirectly between Conductor a and earth and conductor 3 and earth have an inductive load of corresponding Size switches. The .in. The example shown in Fig. I is the latter case shown. The difference, vert, of the charging currents of the secondary windings is indirect via the two transformers c and d through the inductor e in size and direction compensated. The load from the choke coil is practically the same with the increase in the no-load current of the transformers. One can therefore use the Desired compensation also by changing the no-load current of the transformers Achieve that alone, as is well known, in a simple manner by magnifying the magnetic Resistance of the iron core (e.g. enlargement of the air gap) is caused. Do you want an exact balance achieve charging current imbalances, so in the latter case the size of the choke coil is equal to the difference between the capacity power to be compensated and the idle reactive power of transformers. Instead of a third transformer winding for the choke coil You can of course also use them between the corresponding phases of the The generator or on the high-voltage side between the two live ones Lines and earth. Naturally, this compensation can also be applied to any Make points on the route, with and without the help of a special one Transformer.

In the present example, the symmetry of the voltages is brought about by the device f, which consists of an active resistance and a reactance. Their mode of operation can be seen in Fig. A. It is assumed here that tension range and current symmetry exist at the end of the line and that lines ia, 2a, 3a are loaded by three ohmic resistances of equal size connected in a star. The return of phase i may be through earth and its resistance be negligible. If the ohmic resistance in the lines is about 5 percent and the inductive resistance about 15 percent, then at the beginning of the lines we have approximately the voltages ia 2b, ia 3b and 2b 3b, the ohmic voltage drop of the transformers is i percent and the inductive io percent , the three external voltages on the low-voltage side of the transformers are approximately ia 2c, ia 3, and 2, 3 ,. Despite the symmetrical load at the end of the line, the voltage distribution at the beginning of the line and more towards the low-voltage side of the transformers is therefore asymmetrical. The original asymmetry is due to the fact that the return line and the corresponding leg of the transformer have different resistance ratios than the other two lines or the other legs of the transformer. The regulation of the primary asymmetry is now effected in the present invention in that the resistance ratios of the lines and the transformer are artificially changed accordingly. In the example given, to establish symmetry between the interlinking points of the two transformers c and d (Fig. I) and the generator phase i, resistors (reactive and active) are switched on, which correspond to the resistances of a line and a transformer. In this. In this case, the stress point ia (Fig.2) moves to i, and the stress symmetry is thus restored, as can be seen from the stress diagram i., 2c, 3C.

Naturally, the voltage compensation would also have to be carried out in stages can, i.e. initially on the high-voltage side for the primary asymmetry of the long-distance line and then; on the low-voltage side for that caused by the transformers Urasymmetry. In the case of long lines, compensation may also be available the route in question. An absolutely exact compensation is required in the. most cases do not arrive at all. Because the active voltage drop is usually small is compared to the reactive voltage drop and contributes only little to the voltage distortion, on the other hand, however, causes additional energy losses, one will in many cases renounce the compensation of the effective resistance and deal with the compensation of the reactance.

In Fig. I the case is also shown that two systems of characterized by the invention are connected in parallel and that their trunk lines run side by side, for example, are laid on a mast linkage. In this case is a partial compensation of the asymmetrical voltage and Current shift achieved in that the corresponding phases of both Systems are offset from one another by 180 ° (in Fig. I, for example, by reversal the high-voltage connections shown). With this switching method you can achieve the Advantage that with two systems the compensation devices required for the single system need not be doubled. The same can be said of the transformers achieve if you put the high voltage winding of both systems on the same transformers attaches or, which is the same, the middle of the high-voltage winding as a linking point wäh7.t and the ends are used as voltage phases for the long-distance line.

The active or reactive current consumed for voltage equalization Devices can also be placed between two or more interlinking points of phase groups of the system.

Another field of application for the invention is, for example then. available if it is a question of operating a double three-phase system, which consists of two identically designed individual three-phase systems, the high-voltage side are interconnected with a phase shifted by 180 ° from each other (Fig. q.). Then the common phase line lying at the interlinking point becomes currentless stay when both systems are equally loaded, so that there is no need for a special conductor or the interlinking point to earth can be laid. To achieve a desired degree of symmetry at the point of consumption is also here according to the invention the installation of reactive and possibly active current consuming devices (Fig. 4a and b or a 'and b'). the corresponding Resistances of an isolated phase line are to be provided. The one you want The degree of symmetry remains here even if one of the two three-phase systems is is out of operation and the power return of the individual system remaining in operation takes place over earth.

Claims (1)

PATENT CLAIMS: i. Chained, through its design, in particular through simplified circuit or or and line design between supply and take-off circuit or circuits asymmetrical multi-phase power transmission system, characterized by active or reactive current or both consuming devices variable or unchangeable resistance, which directly or indirectly for the production of any Degree of voltage symmetry in the power transmission system itself and regardless of the useful loads between the interlinking point and one or some of the phases or between two or more interlinking points of phase groups are switched on, and other active and / or reactive current consuming devices that are used to balance the currents of the system only indirectly or can be switched directly between individual phases of the system. z. Chained L \ .Iehrphasensystem, characterized in that the connection of a phase at one or more points with earth or their weakly insulated or bare laying or their at least partial replacement by earth or the use of lines of other material (z B. iron) or a different cross-section or resistance coefficient different from the other lines (e.g. copper lines) while maintaining a desired degree of symmetry. 3. Chained multiphase system according to claim i or z, characterized by the use of a V - circuit in such a way that between the interlinking point of the low-voltage side or that of the high-voltage side of the power plant transformer in a V-circuit and the phase belonging to the interlinking point reactive and possibly active resistances for balancing of the voltages are switched on, while other reactive and, if necessary, active resistances placed between individual phases of the system serve to balance the currents. Chained multiphase system according to claim i or the following, characterized in that it is used in two or more individual systems of the same type and size (e.g. g, i, h and g ', i', h ', Fig. I) for transmission the required power is divided and these groups are connected in such a way that the phases of the voltages or currents in the branches of a system by 180 ° in their phase with respect to the voltages. or flows of the corresponding branches of another system are shifted and such individual systems are brought into relation with one another in such a way that the corresponding branches of the systems mutually influence one another electrically and a partial compensation of the asymmetries of the individual systems is brought about. 5. Chained multi-phase system according to claim 4, consisting of a double three-phase system, characterized in that a branch of the one, three-phase system with the corresponding branch of the other, three-phase system shifted in its phase by 18o 'is interconnected, so that the currents in These two branches compensate for each other and a common line of smaller cross-section can be used for them or such a line can be omitted entirely. 6. Chained multiphase system according to claim 4 or 5, characterized in that each of the individual systems or only one of these contains additional compensating devices according to claim i, in particular for the purpose of switching off individual branches of one of the systems or an entire individual system in the other remaining switched on Individual system to be able to maintain a desired degree of symmetry.