DE904920C - Control device for step switching of transformers with high speed resistance regulator - Google Patents

Description

According to an earlier proposal, for 'the Step switching of transformers by synchronous release operated high-speed resistance regulators used. These rapid resistance regulators change within a half wave or within of fractions of a half-wave a resistance value in its order of magnitude. They consist, for example, of one along a resistance track moving 'contact. When the contact wanders along the track, the resistance changes preferably continuously according to a certain function. The ends of the resistor are in contact a switching stage, while the movable contact is connected to a load line. The rapid resistance regulator but can also consist of two elements, the resistance tracks of which are only connected to a step contact at one end are. When switching from stage to stage, the moving contact of one element moves from the position of the lowest resistance value to the position of the highest resistance value, while the movable contact of the other element moves from the highest resistance position to the lowest resistance position emotional.

In a known regulating device for transformers, in which during the transition from 'one level to the other temporarily Switching means is switched on, in addition to the switch for the switching means, an over-

bridging switch used at the beginning of the Control movement opened and only again after actuating the switch for the Überehaltmittei will be closed. By using this bypass switch receives- -man- pre- burnup Protected contacts. for permanent employment. It is also known to use energy storage devices of this type to press!

Also known is a load switch device for step control devices, which consists of a main or bridging switch and an auxiliary switch, in which only the auxiliary switch performs the load switch in cooperation with switching resistors. The contacts of the ¹ NO main or bridging changeover switch are always free from burn-up and can be designed with large contact masses, as the bridging changeover switch is moved slowly.

The application of the known designs Step control devices with high-speed resistance regulators would lead to great trouble. On the one hand, the mass of the .to be moved Parts are so large, especially at higher currents, that the resistance regulators are affected required short switching time of about a half-wave or even shorter not achieved can be. On the other hand, there would be the risk that if the drive fails Control device created by the bridging switch to the high-speed resistance regulator Parallel connection is not made and the resistor body of the regulator through Overload is destroyed.

According to the invention, these disadvantages are avoided in that in the operating positions of the control device through the bridging switch an essentially current carrying the operating Parallel connection between the power supply line of the fast resistor regulator and the activated tap is established and that both the high-speed resistance regulator as well as the bridging switch are each assigned an energy storage device is operated by a common manual transmission.

The advantage of the device according to the invention lies in the reduction of the space requirement and the cost of materials in particular, however, in "that" the triggering by a synchronous control device is made possible that a further reduction of the effort or the same Effort to cope with 'significantly larger step performances allowed. It is further advantageous that the wear is much less than in the case of the known regulating devices. So that will but the service life and the operational safety of the device are extremely increased. Such Control systems require a minimum of maintenance.

With the inventive. Arrangement can the gearbox can be designed, for example, so that after opening "the bridging switch the synchronizing release for the

- provides steady speed regulator. The bypass switch can have such a laziness that "it only works after the speed regulator has been actuated reaches the new closed position. Instead, you can also use the bypass switch with one-of-a-kind resistor speed regulator controlled locking device provided that a Close the bridging switch before closing the termination of the control process of the speed regulator prevent.

Exemplary embodiments of the invention are shown in the drawing.

In Fig. Ι ι the controllable winding with the step contacts 2 and the step selectors 30, 31, of which one the even-numbered, the other the odd-numbered contacts in (known manner • coated. 4, 5 are the two load lines, 6 is the Resistance high-speed regulator, 7 the bridging switch, S the synchronous release. The resistance high-speed regulator consists of two elements 61, 62 which, as FIG. 2 shows in detail, have an opposing switching movement connected to the one tap selector 31 and to the contact 73 of the bridging switch 7, the end 65 of the other resistance line is connected to the contacts 71, 72 of the bridging switch 7 and the load line 4. A corresponding circuit is shown by the resistance paths of the element 62. The movable contacts 66, 67 of the two elements have a common one, for the sake of clarity through a backdrop 6 8 indicated drive, the slots 6g of which are shaped so that the contacts 66, 67 are moved in opposite directions, and ziwar so that first the movable contact 66 is brought into the position of the greatest resistance, in which the contact 67 remains for the time being , and only then the contact 67 is brought into the position of the lowest resistance value. One end of a spring 10 serving as an energy storage device is attached to the link 68, which is mounted so as to be longitudinally displaceable, the other end of which is attached to the switch drive 11, which is also mounted so as to be longitudinally displaceable.

The synchronous trigger 8 consists of one of the load line current excited magnet system 83 with associated pivotable yoke part 84 and a movable plunger 81, the part 84 standing by the acting on it, under the pressure of the yoke Spring 85 is shifted downward as soon as the spring force outweighs the holding force of the armature 82; that is just before the zero crossing of the load current.

The link 68 of the high speed resistance regulator winds in each of the two end positions through a pawl 12 locks / unlocks the movable part 81 (Plunger) of the Synchronauslö'sers-8 acts. Of the pivotable yoke part 84 of the synchronous release is by means of the through the link slot 13 of the Link 14 actuated linkage 15 moves. the Link 14 is still with a further slot 16 provided, which actuates the movable contact 75 of the 1:25 bridging switch. The backdrop will be 14

locked in the two end positions by pawls 17, 18 which are disengaged by a pusher 19 connected to the drive part 11. Furthermore, the link 14 is connected to one end of a spring 20 serving as an energy storage device, the other end of which is fastened to the drive part 11. The device works as follows: In the position shown, the load line is connected to the tap selector 31. The high-speed resistance regulator element 61 is bridged by the contacts 71, 75, 73 of the bridging switch 7. If you now want to switch to the step selector 30, the drive 11 is moved in the direction of the arrow. It loads the energy storage springs 10, 20, since the links 68 and 14 cannot follow the movement of the drive part 11 due to the blocking by the pawls 12 and 17. After the energy storage device has been charged, the pusher 19 releases the pawl 17, as shown in the drawing, so that the link 14 is quickly displaced in the direction of the arrow. During this shift, the contact 75 of the bridging switch 7 is first lifted off the contacts 71, 73, and thereby the bridging of the high speed resistance regulator element is canceled As soon as the load current passes through zero or shortly before that, the armature 82 is torn loose by the spring 85, and the movable part 81 disengages the pawl 12. The now released link 68 suddenly moves in the direction of the arrow the element 61 is first set from the short-circuit position to the highest resistance value, then the switching element 62 is brought from the highest resistance value to the short-circuit position high that this Ele ment carries practically no electricity and as a result the tap selector connected to it is practically without electricity. The load circuit is practically not influenced by the processes at the high speed resistance regulator if, through suitable coordination, e.g. of the inertia forces, it is ensured that the moment when the moving contacts 66 and 67 of the high speed resistance regulator are simultaneously set to the highest resistance value, with the zero crossing of the Load current coincides. The backdrop 68 has just covered half its working stroke. The course of the past in the course of the load line 4 the resistance value R 'of the resistive Quick regulator in dependence on the stroke of the slide · ί 68 shows the curve 2 ¹ I in Figure 3. Having now described. As described, the load current has been transferred from the step selector 31 to the step selector 30-, the bridging switch 7 is closed again through the slot 16 in that the movable contact 75 bridges the contacts 74, 72. Finally, the yoke piece 84 is removed from the magnet 83 again through the slot 13 and the synchromesh release 8 is thereby brought back into the initial position shown.

The now currentless stage selector 31 can now be switched to a different voltage stage will. If the load circuit is now to be adjusted to the voltage level, the drive will 11 moves in the opposite direction. The processes are essentially the same; The only difference is that here the scenes 68, 14 in the left end position by the Pawls 12 and 18 are locked and the pusher 19 now the pawl 18 disengages.

One can, however, proceed differently by operating the high-speed regulator in such a way that about half of the working stroke of the link 68 is covered at the zero crossing of the step voltage. In this case, the excitation winding of the magnet 83 of the synchronous release 8 is connected between the two stage selectors 30,31 (Fig. 4) or any two points of the rule winding 1 (Fig. 5). , In the case of FIG. 4 it is advisable to switch to the exciter winding of the synchronous shutter 8 a capacitor in parallel, in order to avoid "switching fire at the steps voters-3 ¹ O ^1, 31. In the embodiment of Fig. 4 and 5, the slots 69 6, which differs somewhat from that shown in FIG placed and then 61 transferred to the other member from the Kurzschlußstellunig in the position of the largest resistance value. the two switching movements can temporally overlap somewhat in the process. in this case the result for the past in the course of the load line 4 resistance value R of the resistance Quick regulator 6 by the curve 22 in Fig. 3. In the course of this curve the resistance value is almost zero, but this is i ° 5 pr Actually -without influence on the equalizing current, since this resistance value-coincides with the zero crossing of the transformer voltage, so only an insignificant Ausgieiehsstrom can come about. The embodiments according to FIGS. 4 to 6 are therefore; particularly advantageous because here the synchronous release 8 is constantly on, the same voltage, i.e. always has the same excitation, while in the embodiment according to FIG The switching when the voltage crosses zero offers the advantage that the resistance elements of the high-speed resistance regulator are subjected to little thermal stress.

"Figure 7 shows a similar implementation Tim: Here the parts corresponding to FIG. 1 are provided with the same reference numerals. The rapid resistance regulator has only a single element here with a resistance track 601 and a movable one

Contact 600. For this are here but the two ends of the resistive track with the Stufeinwählern 30, 3 ¹ and the contacts 76, 77 of the Uberbruckungsumsehälfars 7. The mode of operation is basically the same as in FIG. 1, but here the force storage spring 10 for the actuation of the resistance fast regulator 6 is only charged indirectly through the link 14 of the bridging switch 7.

In FIG. 8, an embodiment of an element 61 for a high-speed resistance regulator is shown approximately in natural size with switching capacities for regulating transformers of approximately 100 MVA throughput. The movable contact 66 here consists of a metal piece 660 with an adjoining resistor body 661. 63, the resistor tracks as in FIGS. 2, 64, 65 are the metal connection ends of these tracks. The contacts are enclosed in an insulating housing 602, through the end walls of which an actuating rod 603 for the movable contact 66 is led out. The gaps in the rod are encapsulated by metal bellows 604. In place of the metal bellows also 'by curved membranes ² S occurred, the same' can replace the can end walls of the housing 602 and at Hinundherbewegenj of the movable contact, by tilting.

Since, as FIG. 8 shows, the high-speed resistance regulator turns out to be very small and) furthermore the bridging switch is not operated under load, i.e. it can also be made small, these devices can be conveniently used together with the synchronous release, as FIG. 9 shows Place above the step selector 300 in container 3.01 of an oil transformer or in the step selector boiler. Since no arcs occur during operation on any of the control elements, the oil container in which they are located can be secured by a known protective device that responds to gas formation or oil flow. As FIG. 9 shows, the tap selector and the various elements 7, 8, 61, 62 are located on a carrier carrying the operational potential, which is fastened to the boiler 301 by insulators 302 for operational potential. Above the elements is the container with a cover 303 through which the individual elements can be exchanged remaining parts of the switching device connected. In the case of a multi-phase arrangement, each phase has a synchronous release, a high-speed resistance regulator and a bridging switch. The bridging switches of the three phases can be coupled with one another, i.e. they can be switched over at the same time. Even if a sufficiently rapid switching through of the high-speed resistance regulator can be achieved because of the small switching mass, it is often not possible to ensure that the high-speed resistance regulator and its gear are activated immediately when the synchronous release is triggered. This delay can be compensated for by bringing the response time of the synchronous release forward. It is recommended, for. B. dbn synchronous release to respond to one or more half-waves earlier and to adjust the inertia of the high-speed regulator and its gear so that, as already mentioned, the working stroke of the gate 68 (Fig. 9) controlling the high-speed regulator is already half executed when the load current and the step voltage go through zero. The duration of the total stroke of the high-speed resistance regulator is expediently shorter than the half-wave duration of the load current or the step voltage.

Claims (10)

PATENT CLAIMS: r. Control device for level switching of transformers with high-speed resistance regulators, preferably controlled by synchronous releases, characterized in that in the operating positions of the control device by a known bridging age (7) ekie in the essential operating current leading parallel connection between the current lead of the high speed resistance regulator (6) and that the tap is switched on and that both the high-speed resistance regulator as well as the bridging switch, one energy storage mechanism each (10 or 20) is assigned, which are operated by a common gearbox (11, 14, 68, etc.). 2. Control device according to claim 1, characterized characterized in that the gearbox after opening the bridging switch (7) the Synchronous release (8) for the resistance, fast regulator (6) provides and that the Überbräckungswalter (7) has such inertia that it only occurs after the resistance. (6) reaches the new closed position (Fig. 1). 3. Control device according to claim i, characterized in that the gearbox according to the open the bypass switch (7) the ω Synchronous release (8) for the rapid resistance regulator (6) provides and that the bypass switch with one of the high speed resistance regulator controlled locking device is provided, the eirn reclosing of the bridging switch before the end of the control process of the high speed resistance regulator prevent. · 4. Control device according to claim 1, in which the resistance quick control consists of two elements moving in opposite directions, characterized by a drive device (68, Fig. 6) for the moving contacts (66 and 6f) of both elements (61, 62) which make the contacts in quick succession one after the other in such a way, possibly with partial overlap of the Movement time, actuates that one element (62, Fig. 2) from the high resistance position in the short-circuit position and then the other element (61) from the short-circuit position moves to the high resistance position. 5. Control device according to claim 1 to 4, characterized in that the synchronous release (8, Fig. 4 to 6) shortly before 'the zero passage of the voltage, the high-speed resistance regulator (6) is actuated, if this is the case the switching speed and the tripping time that · the two elements (61, 62, Fig. 2) of the high speed resistance regulator * 5 (6) reach the short-circuit position just when the voltage crosses zero. 6. Control device according to claim 1 to 5, characterized in that the bridging switch (7, Fig. 7) charges the energy store (10) of the high speed resistance regulator (6) during the opening movement before the synchronous release is provided. 7. Control device according to claim 1 to 6 for oil transformers, characterized in that the high-speed resistance regulator (61 or 62) in an oil-proof housing (602, 604) inside the transformer oil container! (301) or des Stage selector container is preferably arranged directly above the stage selector (300) (Fig. 9). 8. Control device according to claim 1 to 6, characterized in that the bridging oil switch (7) in the transformer's oil tank. (301) preferably above the Step selector (300) is arranged (Fig. 9). 9. Control device according to claim 1 to 8, characterized in that the high speed resistance regulator Electrically connected by plugs and mechanically connected to the rest of the control device by pull-out couplings is. 10. Control device according to claim 1 to 9 for multi-phase transformers, characterized in that for the individual phases from each other independent synchronous releases and high-speed resistance regulators are provided, but that the bridging switch of the individual Phases are coupled to one another. 1 sheet of drawings 5767 2.54