DE603566C - Control transformer with two alternating and step-wise working tap changers per phase - Google Patents

Description

Regulating transformer with two working alternately and gradually Step selector per phase The invention relates to a regulating transformer with at least two tap selectors connected in parallel, whose contacts are connected in pairs to the taps the adjustable winding are connected. The level selectors are alternating operated in such a way that first one is connected in advance by one voltage level and then the other is connected downstream to the same voltage level. The level selector are connected to the load circuit via a load switch. The load switch de-energizes the tap selector that carries out the switching movement.

If now the first step selector in the de-energized state by one voltage step is connected upstream and the second step selector is connected downstream to this step is to be, the load current must be switched from the second to the first tap selector will. So at the moment of this changeover, in which a stage is temporarily is bridged by the load switch, the equalizing current is not too high values one can assume. a preliminary contact between the contacts of the load switch attach, through a resistor or a choke coil to one of the main contacts connected is. In the case of transformers with a high output, in particular in the case of transformers with very high currents, these resistors or inductors drop a lot large, they take up a lot of space and are very expensive. The invention eliminated this disadvantage. According to the invention, at least between a main contact and a pre-contact of the load switch instead of the resistor or the choke coil an additional winding of the regulating transformer, with a higher spread than that of the primary and secondary windings, switched on. This extra winding generates a voltage of such magnitude that the potential of the pre-contact between the potential of the neighboring main contact and the neighboring pre-contact of the Load switch lies. This additional winding can either be on a special, auxiliary transformer connected to the excitation voltage of the main transformer or on the iron core of the main transformer itself. Particularly the last embodiment is advantageous because it has the main transformer as well no further auxiliary apparatus is required. To the transformer winding in the pre-contact branch To give a large spread, the best is a spread of xoo ° / o, one can the air duct between this winding and the excitation winding is correspondingly wide dimensioned, or you can reduce the spread by attaching special iron-closed Increase spreading paths. In the case of three-phase transformers, a Achieve increased scattering that you have the transformer winding in the pre-contact branch the one phase on one or both Magnet legs of the other Phases, if possible in the yoke area, accommodates.

The large spread of the pre-contact winding is required so the equalizing current in the positions where the load switch bridges this winding, does not assume impermissibly high values.

To the load on the load switch contact at which this equalizing current Must be switched off to reduce, according to the invention, the equalizing current is given expediently such a phase position that it is through the load current, which is also through passes through this contact, is at least partially balanced. As an an example it is assumed that the load current is in phase with the transformer voltage, the Compensating current but the voltage of the pre-contact winding because of the high scatter the latter lags behind by about go °. If one now ensures that the tension of the Pre-contact winding is shifted by go ° against the main voltage, which is when it is attached this winding can easily be done on the legs of the other phases, so the Aizs DC current is opposite to the load current. It succeeds now, the To make equalizing current equal to the load current, the load switch can be connected to the mentioned Contact can be switched off at all.

Embodiments of the subject matter of the invention should be based on the Schematics of the drawing are explained.

In Fig. I i is the primary winding, 2 the secondary winding, 3 the pre-contact winding of the transformer. The secondary winding has taps 21 to 25 which are connected to the contacts in to r25 of the step selector zoo and to the contacts 221 to 225 of the step selector 2oo. The stage selector ioo is connected to the contacts 501, 5o2 of the load switch 5oo, the stage selector Zoo to the contact 5o3 of the load switch. The third winding 3, which is connected in series with a resistor 505 and a choke coil 506 for balancing the equalizing current, is connected between the main contact 503 and the pre-contact 504. One or both of the resistors 505, 506 can be omitted, and the balancing current can be adjusted by regulating the scatter of the winding 3, for example by means of displaceable iron parts. The consumer circuit is connected to the load switch 5oo and to the end 26 of the winding 2.

The load switch 5oo, which is designed as a rotary switch, is through the bevel gears ior and the Maltese cross gear 102, 103 with the step selector ioo, through the bevel gear toi and the Maltese cross gear 2o2; 2o3 with the step selector Zoo coupled.

The control takes place in the following way: The position shown corresponds to the greatest voltage. If the voltage by one level can be lowered, the load switch 500 is rotated in the direction of the arrow 5o7; as soon as it has left contact 502 , step selector ioo is switched from contact izi to contact i22. When the load switch reaches contact 504, winding 3 is bridged (dashed line position), and the equalizing current indicated by dashed arrows 508 flows in addition to the load current indicated by solid arrows 2o.

As soon as the switch 500 leaves the contact 503 , the direct current is interrupted; the voltage of the winding 3 is now made up of the voltage of the winding 2. In terms of magnitude and direction, the voltage of the winding 3 is at least dimensioned so that in this position the potential of the contact 504 is not higher than that of the contact 503. But one will go further and ensure that the potential of the contact 504 lies between the potentials of the contacts 503 and 501, so that an excessively high equalizing current does not occur when the load switch 5oo is turned further. It is expedient to make the voltage of winding 3 equal to half the voltage of a winding stage of winding 2 and to switch the windings so that the EMFs are subtracted. It then sinks at the transition from contact 5o3 to. Contact 504 increases the voltage by half a step and when changing from contact 504 to contact 50I again by half a step.

For the. Choice of the voltage of the winding 3, but also others Considerations are decisive, in particular the relief of the contact 503 which the equalizing current 5o8 with the further rotation of the load switch from the dashed line position shown must be switched off =. -This contact can be almost complete be relieved if, as mentioned, one takes care of this. Job the load current 2o. and the. Compensating current 5o8, cancel each other.

. When switching the load switch from contact 504 to the contact 501 temporarily becomes the voltage level between the taps 2z ,, 22 bridged; however, the resulting equalizing current is passed through the winding 3 strong depressed - As soon as the load switch has left contact 504, will the step selector Zoo switched to contact 222. The load switch will then rotated further via the contact 502 into the position shown .. In the same We will proceed with each of the following Regestufa:

In order to increase the spread of the winding 33u, it can be arranged on the individual legs of the three-phase transformer according to FIG. 2. Here the winding 3 is divided into two parts 3a, 3b. Assuming that the associated main winding 2 belongs to phase S, the winding parts 3a, 3b are arranged on the magnet legs of the two other phases RT as close as possible to the yoke; this results in a high degree of scatter. In the exemplary embodiment, the winding parts 3a, 3b are dimensioned and connected in such a way that the resulting voltage 31 (FIG. 3), which is composed of the components 32, 33 with the phase position of the voltage vectors RT, is approximately about go ° the voltage vector S of the main winding 2 lags behind. The equalizing current 5o8 (FIG. 3), shown in dashed lines, is shifted in phase with respect to voltage 31 by almost go ° because of the high scatter of the winding 3; Compared to the vector 2o of the load current, which only slightly lags the voltage S, the compensating current 5o8 is almost shifted by 180 °, the two currents therefore cancel each other out except for a small residual amount, so that at the contact 503 (Fig. x) only small energies have to be switched off.

Another means of reducing the equalizing current is shown in FIG. Here the load switch 5oo consists of a so-called snap switch. In addition, a transformer winding is not only connected between the contacts 503, 504, winding 3, but also between the contacts 501, 502, winding 35. The voltages of the windings 3 and 35 are dimensioned such that the potential of the contact 504 around the third Part of a voltage level is lower than the potential of contact 503, the potential of contact 501 is higher than that of contact 502 by the same amount. The movable contact of the circuit breaker 500 and the fixed contacts 5oi to 504 are dimensioned and arranged such that between the contacts 503, 504; 504, 501; 501, 502 a lock-up never occurs at all; the length of the movable switching contact is smaller by the amount a than the distance between these contacts, measured in radians. The distance a is dimensioned in such a way that it cannot be bridged by an arc fed with the voltage of a stage or the third part of a stage, but can easily be bridged by the arc of the load current fed with the total voltage. At the transition of switch 5oo, for example from contact 503 to contact 504, an arc therefore only occurs until the movable contact part touches contact 504, i.e. only as long as the load current has no other option to reach the movable contact part to get. At the moment when this reaches contact 504, the arc at contact 503 is extinguished, since the voltage of winding 3 is not sufficient to maintain this arc. The equalizing current is considerably reduced by the resistance of the arc; therefore, under certain circumstances, the spread of the windings 3 and 35 in FIG. 4 can be kept significantly smaller than the winding 3 in FIG.

So that the arc does not cause any damage, it may only be used briefly, for example, occur only during the thousandth part of a second. Such Switching times can easily be achieved with snap switches. These switches act in such a way that the movable switching part is initially prevented by a locking mechanism will follow the movement of the handle to which it is connected by a spring is. The spring is then tensioned. Once the handle has a certain position reached, the lock is triggered and the movable part of the switch is under the action of the tensioned spring at high speed into the new one Positioned in which he is also held by a lock.

In the embodiment according to FIG. 4, between the contacts 503, 504; 504, 501; 501, 502 and vice versa the switching movement takes place abruptly. In contrast, this is not necessary between the contacts 502, 503.

Claims (7)

PATENT CLAIMS: i. Control transformer with two alternating and gradual working tap selector _ per phase, their symmetrically located fixed contacts are connected to the same taps of the control winding and with a load switch each phase, which has two main and two previous contacts, of which one main and a pre-contact connected to the movable part of the associated tap selector are, characterized in that at least the on the movable part of the one Step selector (2oo) connected main contact (5o3) of the load switch (500) an additional winding (3) of the regulating transformer, with a higher spread than that of the primary and secondary windings (i, 2), with the associated pre-contact (5o4) of the circuit breaker is electrically connected and that the additional winding generates a voltage of such magnitude that the potential of this pre-contact (5o4) between the potentials of the neighboring main contact (5o3) and the neighboring one Pre-contact. (5oi) lies (Fig. I). 2. Transformer according to claim i, characterized in that the transformer mounted matorwicklung 0 (3) in the current branch of the preliminary contact on an auxiliary transformer, whose other winding is connected in parallel with the excitation winding of the regulating transformer. 3. Transformer according to claim i, characterized in that the additional winding near the yokes of the Control transformer is attached (Fig. 2). 4. Transformer according to claim i, characterized in that the main contacts (502, 503) of the load switch connected to the moving parts of the tap selector (ioo, zoo) each have an additional transformer winding (35.3) with the associated pre-contacts (5oi, 5o4 ) are connected and that the voltages of the additional windings (35, 3) are dimensioned such that the potential of one pre-contact (504) is lower by the third part of a voltage level than the potential of one main contact (5o3), the potential of the other Precontact (5oi) is higher than that of the other main contact (5o2) by the same amount. 5. Transformer according to claim i in three-phase design, characterized in that that the additional winding (3) leading to the pre-contact branch of one phase (S) of the Transformer is attached to the two magnetic legs of the other phases (RT) is (Fig. 2). 6. Three-phase transformer according to claim 5, characterized in that that the voltage vector (3i) of the additional winding (3) by about go ° the voltage vector (S) lags the main winding (2) in phase (Fig. 3). 7. Transformer according to claim i, characterized in that with the additional winding (3) in the pre-contact branch a resistor (5o5) or a choke coil (5o6) is connected in series (Fig. i). B. Transformer according to claim i, characterized in that the distance between two contacts of the circuit breaker, measured in radians, around such a piece (a) is greater than the length of the movable contact part that it is affected by the tension in the additional winding (3) not fed arc, however, that of the Total voltage fed arc can safely bridge (Fig. 4). G. transformer according to claim 8, characterized in that a snap switch is used as the load switch is used.