DE733558C - Arrangement of three-phase transformers or three-phase choke coils with additional windings - Google Patents

Description

Arrangement of three-phase transformers or three-phase reactors with additional windings The invention relates to three-phase transformers with Additional windings. * According to the invention are the primary and secondary windings one or two transformers, each with a switchable fixed additional winding which each cause a phase shift of the voltage against the flow of -f- z5 ° and by interconnecting with the main windings an o ° or 3o ° circuit result in the same tension. For this purpose, the main windings can be associated with the Auxiliary windings form a zigzag or star-delta mixed circuit. Particularly A star-delta mixed circuit for the primary and secondary windings is advantageous of the transformer or m. The arrangement according to the invention brings, as on hand of the embodiments explained in more detail, with one or two "transformers Advantage that the transformers by simply switching taps both with in star-star and triangle-triangle as well as with in star-triangle and star-zigzag switched 'other transformers can work in parallel at any time. Through this the storage and reserve management becomes with a small one-time additional expenditure for copper extremely simplified, and it saves on installation costs.

The arrangement according to the invention also has, as in the following explained in more detail, the further advantage that by connecting two in parallel according to of the invention trained transformers or by. Parallel connection of these Transformers with transformers of the usual circuit those of the transformers can largely eliminate the harmonics caused. So you can use these transformers run for higher iron saturation and thus significant savings in iron and Achieve copper without any direct disadvantages (harmonics) or indirect disadvantages (no possibility of primary and secondary parallel work and poor interchangeability) occur. It is already known per se on transformers by switching the windings a phase rotation between the flux and the terminal voltage of the transformer. However, the condition is not met that both the primary and the secondary winding of the transformer each have one have switchable fixed additional winding, each one phase rotation of the voltage against the flow of -F-15 °. The known transformers therefore have also not the advantages described, in particular with regard to parallel connection with connected in star-star, triangle-triangle or star-triangle or star-zigzag other transformers. .

The invention also relates to three-phase choke coils that operate finitely with iron saturation. According to the invention, two (nasty choke coils are each provided with a switchable fixed additional winding, each of which gives a phase rotation of the voltage) cause the flow of the choke coil from -f- i5 'or -i5-', so that by connecting two choke coils in parallel, one of which at the one of the flux is rotated by -! - 15 'with respect to the voltage, the other by - 15', the fifth and seventh harmonics evoked by the choke coils cancel each other out.

Other harmonics can - as described at the end of the description, Eliminate when you add saturated reactors to those saturated reactors switches in parallel, which on the one hand no phase shift between voltage and Have flow, on the other hand, e.g. B. as a result of three, ecl: circuit, a 30 ° -plaase shift. The arrangement according to the invention therefore gives similar advantages in the case of inductors as with transformers, since you can turn the choke coils to save iron and copper for high iron saturation can run without affecting the direct material part the occurrence of harmonics occurs or the indirect disadvantage of bad Interchangeability.

The drawing shows exemplary embodiments of the invention. In Fig. I a transformer is shown which is connected both primary and secondary in zigzag such that each of the two windings rotates the voltage by 152 relative to the flux. The number of turns must therefore be chosen so that the number of turns of the two parts of the primary winding or the secondary winding lying on one leg are connected to one another as sin d.5 'to sin i5 °. Since both @@ iclclun, @ en a rotation of tension by -; 1.5- compared to the flow of the fundamental wave r_usfübren, the resulting rotation of the voltage to-islalen the input terminals''1', TI- and the @ usganb.sklemme : r. v, deich zero, so claf, you can work with such a transformer in parallel with vector groups A and B, d. 1i. z. B. niit star-star or triangle-delta connected transformers can be used. The same result is achieved if the sign of all angular rotations is reversed by simply switching the phase sequence of the connections, so that the voltage is rotated by - i 5 J 'for each winding with respect to the flux.

But if you only turn (read the sign of one of the two windings Phase sequence switch to, like that in Vi-. a is shown for the secondary winding. so one and the same transformer now gives a rotation of 4-30 @ or -30 ° between Input and output voltage and can now work in parallel with the transformer £ # n of groups C and D, e.g. B. switched to star-delta or star-zigzag Transformers are used. 'Mail c r - thus holds a transformer in this way, its range of application is significantly expanded with the same operating voltage has been.

If there are two transformers of this type, they will be connected to the same voltage lying windings switched so that one dun flux around + i5 =, the other uin - i5 in its phase position opposite (for operating voltage twisted, and have the two transformers have the same induction tinrl magnetization power, so When connected in parallel, the fifth and seventh harmonics stand out. That would therefore apply, for example, if nian only has transformers i and 2 on their undervoltage side switches in parallel. If you wanted them on the high voltage side too parallel `switch. so one would still have to determine the phase sequence of the high-voltage winding reverse from a transformer.

Instead of switching the transformers in a crooked zigzag, Idinnte nian them too, as in Fib. 3 shown. switch in delta and taps the Lead out triangular winding # 2n: The taps are chosen so that another Turn around -; - i 5 or -i5 - takes place. There are in every winding in this one If two taps are necessary. thus depending on the choice of the connection point a -, ' i-5 - rotation o # ler - i 5 rotation can be brought about.

It is particularly useful to use a star-delta mixing circuit as shown in FIGS. 4, 5; 6 and 7 is indicated. In the star-delta mixed circuit, e.g. B. according to FIG. 4, the windings get taps, and the end points of the winding that are not connected to the network are connected to these taps in such a way that a delta connection is formed, as the exemplary embodiment shows. 4 shows a circuit in which both the primary and secondary windings have a triangle -Iisct circuit, each winding rotating by + 15 ° of the voltage with respect to the flux. As a result, here too, similarly as in Fig. I, all of the voltage rotation between the input terminals U, Il, W, and the output terminals u, v, w zero, so that the transformer can be operated in parallel work with the switch groups A and B. The same applies to the arrangement according to FIG. 5, in which the sign of all angular rotations is reversed. If one only reverses the sign of one of the two windings by phase sequence switching, as shown in FIGS. 6 and 7 in the two possible versions, one and the same transformer now results in a drift by + 30j or -30 ° between the input and output voltage, so that he can work with de, n. switching groups C and D in parallel. You can see that you can always run the transformer uniformly, and that you can only achieve the desired offset between input and output voltage for working with other transformers by switching the phase sequence.

If you switch the transformers of Fig..I and 5 or those of Fig.6 and 7 in parallel, the fifth and seventh harmonics stand out if the transformers have the same induction and the same magnetization power. This is due to the fact that the transformers of Figures 4 and 5 face the flow the voltage of the network that supplies the magnetizing current by -; - 15 ° or Twist -15 °. The same also applies to the transformers of FIGS. 6 and 7.

These transformers; which the flux versus the operating voltage by 15 ° drelien, deliver the eleventh and thirteenth harmonics at the same time, which in Antiphase to the o ° r waves of the normal o ° and 3o ° circuits, e.g. B. the Star-delta and zigzag connections are available when considering all transformers of the occurrence of the third harmonic in the phase flux are the same. It is with this one Always take harmonic compensation into account. that when spoken of the rotation is, always only the rotation of the fundamental wave of the river against the tension of the Network is meant, which supplies the magnetization power. For example, could you connect the transformers of Fig.4 and j in parallel. One would do that too one connected in star-delta (o ° rotation) and one in delta-star (30 ° rotation) Connect the transformer in parallel and all transformers would have the same magnetizing power and induction, the fifth and seventh and also the eleventh would become one another and highlight thirteenth harmonics. At the same time also disappear in this case the seventeenth and nineteenth harmonics.

How the number of turns ratios of the star-delta mixed winding must be selected so that the voltage is offset by 15 ° with respect to the flux is shown in the vector diagram in FIG. This shows the vector image for the circuit according to FIG. a., b, c is the voltage diagram of the delta connected winding, where, as in Fig. q. shown, a., b and c are the tapping points of the overall winding. The triangle U, h, W is obtained if a vector with the same phase position is added to the Viktor b, a, and to the vectors c, b and a, c in a corresponding manner so that the vector U, V compared to the vector a , b by 15 °, Il, W against b, c and W, L 'against c, a. is offset by 15 °. Since Ua. to aW behaves like sin 15 ° to sin: 45 °, a simple calculation gives the number of turns ratio of the triangular WA to the star winding II-a to . The total number of turns N '). + WA must, as one can easily convince oneself, that the number of turns with a pure star connection.

The currents in the star and delta windings must behave in relation to one another as in any series connection of a star and delta winding. The cross-sections of the star qi and the delta winding qA are to be selected accordingly The copper expenditure is therefore divided equally between star and delta windings.

Compared to the normal transformer in star or delta connection the total copper expenditure is only 3.5% higher.

For voltage regulation it is necessary not just taps the star winding, but also at the same time the taps of the triangular winding to regulate to (read the prescribed ratio of star to delta winding to be able to maintain regardless of the translation ratio of the transformer.

In Fig. G it is also shown how you can create the missing star point if necessary by an additional winding. For this purpose, the winding also has taps f, g and? T, to which the star-connected additional winding is connected. The copper requirement of this additional winding depends on the desired load capacity of the star point. The size of the number of turns where the additional winding and the position of the taps f, 11- and h also follow immediately from FIG. It is As already mentioned, if you use two such transformers, one of which rotates by -1-15 °, the other by -15 °, the upper realities in the resulting current stand out. The circuit for saturated choke coils can therefore also be used, the windings of which are then in. Star-delta mixed circuit can be switched. If two identical choke coils are connected, one of which rotates the flux with respect to the voltage by - [- i 5 °, the other by - 15 °, in parallel, the fifth and seventh harmonics stand out. The new arrangement is therefore favorable for choke coils, since two identical choke coils are used finitely with the same winding and the upper realities can only be eliminated by reversing the phase sequence. If the choke coils or transformers lying in parallel are of different sizes, then the saturation must be selected differently to compensate for the upper realities. If you connect two choke coils rotating by + 15 'and - 1 5' parallel to one rotating by o ' (star) and one rotating by 30 ° (e.g. triangle), the fifth are lifted, as described for transformers , seventh, eleventh and thirteenth upper levels.

Claims (1)

PATENT CLAIMS: i. Arrangement of three-phase transformers with additional windings, characterized in that the primary and secondary windings of one or two transformers are each provided with a switchable fixed additional winding, which each cause a phase rotation of the voltage against the flow of -i-15 ° and by being interconnected with the Main winding result in an o ° or 3or 'circuit with the same voltage. Arrangement according to Claim i, characterized in that the main windings form a zigzag or star-delta mixed circuit with the associated auxiliary windings. 3. Arrangement of saturated rotary throttle coils, characterized in that two choke coils are each provided with a switchable fixed additional winding, which each cause a phase rotation of the voltage against the flow of the choke coil of + 15 ° or -15 ', so that by connecting two choke coils in parallel , of which the flux is rotated by + i_53 on one side and by - i5 'on the other, the fifth and seventh harmonics caused by the choke coils cancel each other out. .I. Arrangement according to claim 3, characterized in that two choke coils are connected in parallel to the two choke coils in which the flux is rotated by - [- 15 ° on the one hand and - 1 5 'on the other hand with respect to the voltage, one of which has a twist angle of 0 ° (star connection) and the other has a twist angle of 30 = (z. B. delta connection) between flux and voltage. 5. An arrangement according to claim 3, data carried in that at the two reactors, the main windings with the auxiliary windings zugeordlieten a zigzag or star-delta - form mixing circuit.