DE918461C - Load switch arrangement for step control devices of transformers, chokes or capacitors - Google Patents

Description

(WiGBl. P. 175)

ISSUED SEPTEMBER 27, 1954

(Ges. V. July 15, 51)

The invention relates to a load switch arrangement for step control devices of transformers, Chokes or capacitors. It usually consists of one or more Expediently by energy storage-driven circuit breakers, switching resistors or chokes, control relays as well as step selectors and, if necessary Reversing switches. With their help, the is connected to a control stage of the winding Load line transferred to another level and the direction of control reversed. Such switches are also used to switch the excitation windings on, off and over in the course of the power line Additional transformers can be used. The drive of the switch assembly can be arbitrary, for. B. motorized, hydraulic or by compressed air or by hand. The switch itself happens slowly or erratically.

The object of the invention is, in such load switch arrangements, especially if they have to switch larger currents, the switch design to be taken in such a way that contact erosion is avoided, or at least greatly reduced.

According to the invention, at least the switch-off torque is the greater switching loads subject switch by one of the instantaneous values of the step voltage or the switching current affected relay determined. Furthermore are

the individual components of the switch, e.g. B. the length of the contact lever, the translation of the gear, the Springs and the shape of the contacts, balanced and made adjustable so that that of the pulse generator the time elapsing through the relay until the contact is disconnected in a given fixed resp. adjustable ratio to the period of oscillation of the current to be switched. Most of all you will the contact separation at the switch in a specific or adjustable moment before the Let the switching current pass through zero. But you can also exactly in the current zero crossing switch if it is ensured that the current zero range is wide. This is particularly true for circuits too, the apparatus, z. B. chokes, contain the iron cores of a strongly curved Have characteristic. When using highly permeable alloys, e.g. B. Permalloy or Hypernik and similar substances, the magnetization curve is known to have one or more sharp curvatures. It is advisable to choose an operating point that is on the greatest curvature of the magnetization curve lies.

The advantages are smaller switching paths for the contacts to be switched, space savings and Saving of expensive arc-proof materials.

The relays forming part of the invention speak as a function of instantaneous values the currents to be switched or the voltages driving these currents. Between addressing of the relay and the completed contact break may be a period of time that is one or more Corresponds to half-waves of the alternating current to be switched. This time is determined by the proper times of the Relay, the trigger parts for the switching contact movement, the mass acceleration of the gear and moving switch parts given. Since, according to the invention, the inertia forces are chosen so large that that they outweigh the frictional forces several times, this is a constant period of time. The correct time of the contact break can be determined by changing the proper times of the said Relays, gear and switch parts can be set so that the contact break exactly in the desired Point in time, that is, at a marked point on the half-wave.

All so far with regard to arc-free switching, e.g. B. for oil switch, known Proposals provide for the contact break exactly in the current zero crossing, but with what, especially when switching phase-shifted currents, z. B. when using normal transition chokes Control switches, the desired effect cannot be achieved because there is no insulating distance is present that could stop the voltage recovery from breaking through. Further the means provided for controlling the known oil switch were so unsuitable that up to now such switching processes could not be put into practice. The application arc-free Switching for step control devices offers particularly great advantages precisely because here in the lattfe of a working day many switching operations can play and because the wear and tear of the contacts on the control switches, in particular when these form a structural unit with their transformers, as particularly annoying is felt.

To control the disconnection process, a load switch arrangement designed according to the invention the relay shown in Fig. 1 is used. This consists of the control part 1 and the trigger part 2. The control part 1 has an iron core 4 provided with the excitation winding 3, the when energized, the control armature 5 and the release armature 6- attracts. Via the lines 7 and the Switch 8 and, if necessary, a series resistor, the winding 3 is connected to the one to be switched Current supplying voltage source, e.g. B. on the mains voltage or on a step voltage of the Regulating transformer. The excitation can also take place from a current transformer, which is in the Load line or in the equalizing circuit of the regulating transformer. If now the load switch is to be switched can by the drive mechanism of the movable load switch contact the switch 8 can be closed so that the control relay is in the ready position. For example the contact 8 can be driven by a spring-loaded energy storage device after charging has been completed or be switched on by a centrifugal switch that responds when the flywheel mass required speed. The control part 1 attracts the control armature 5 and the release armature 6. The armature 5 then closes the switch 11 and the DC excitation 9 of the winding 10 of the trigger part 2 switched on. The tripping armature 6 is now under the action of two Fields. At the moment when the current in coil 3 goes through zero or approaches zero, the force of the direct current magnet 2 predominates, so that the tripping armature 6 is torn from the control part 1 will. He turns on the switch 12, which closes the trigger circuit of the energy storage device. This contains, for example, an electromagnetic pawl in spring-loaded energy storage devices Disengaging the energy store is released so that it is on the movable switch contact discharges. In the case of energy storage devices that consist of a rotating flywheel, an electromagnetic Clutch are operated, the in the desired or set time Flywheel or the drive motor with the The contact to be switched is coupled.

The design of the release part 2 can be any. It only has to be given with a specific and possibly adjustable instantaneous value of the current curve can be actuated by control part 1. It is essential that the movement of the switch contact by a to the instantaneous value of the switching current responsive control part, z. B. a relay is triggered so early that the Contact is broken at the desired time.

The operating time of the relay can be adjusted by means of series resistors, through adjustable air gaps of the

Relay core, by short-circuit windings on the relay core or other means of changing the relay time contacts can be set.

In the case of DC-excited release magnets 2, a battery, a rectifier, z. B. an electron tube or an oxide cathode rectifier, or another direct current source be used.

The trip armature 6 can, however, also in the manner shown in FIG. 2 with the aid of a permanent magnet 13 taxes. This is via an engine, e.g. B. a linkage 14, from the control armature 5 of the Control part 1 brought so far to the release armature 6 that the release armature 6 in the area of action of the permanent magnet. This is then approximately in the dashed position 15.

In order to reduce the masses to be moved, it is advisable to arrange the permanent magnet 13 firmly, so that the anchor 6 in the effective area

ao of the permanent magnet, and shield the trip armature 6 from the permanent magnet by a magnetic screen which is controlled by the armature 5. This consists z. B. from an easily magnetizable iron, which when the armature 5

a5 between the permanent magnet and the armature 6 is folded out or swiveled out so that the permanent magnet acts on the trip armature 6 can. Of course, you can also apply a compressive force through the armature 5, e.g. B. a spring force accumulator, so control that it sets the release part 6 under a mechanical counterforce that the armature 6 opposes the effect of the alternating field from the iron core 4 seeks to tear off.

It is essential for the operation of the control relay merely an arrangement in which the armature 5 exerts a force on the release armature 6 to act brings, which strives to tear this from the core 4, so that it is at zero current passage or at a current value in its vicinity drops and the contact movement is triggered.

Such a device would of course be caused by the load current (when feeding the Relay by current transformer) or by the constants of the magnet system (when feeding the Relay with voltage converter) switch given power factor and thus in the rarest of cases in the ideal case with a power factor of the load current equal to ι and ohmic transition resistances or with a power factor of the load current equal to ο and inductive transition resistances meet the requirements. Here, the o, o ° phase shift of the load current also because of the fact that the power factor equal to ι in the network the voltage to be regulated is perpendicular to the phase voltage (cross regulation). In most cases, however, the phase position of the load current is variable and deviates from the phase position of the equalizing current. The one after the other during a switchover process The load and equalizing currents to be switched are therefore mostly correct in their phase positions do not agree with each other. The phase position also shifts with the size of the load current.

The phase position of the total current from compensating current and load current also deviates again depends on the two components mentioned.

With a given, practically unchangeable power factor of the load current, Setting the proper times of the control relay and the moving gear and switch parts are the most favorable Switching ratios can be approximately achieved by the switching time and the sequence the switching processes are relocated so that the shutdown processes in the expected Power factor and an average power take place shortly before the current zero crossing. So that will A longer arc duration is accepted at lower loads, while at full load if possible is switched close to the current zero crossing. The mentioned proper times can probably be dependent on of the phase shift that occurs and changes with the load or control automatically depending on the load on the regulating transformer, but that makes a difference further additional device required.

Another way of solving the difficulties caused by the success of two switching operations with mutually phase-shifted and in their phase position depending on the load alternating currents arise, at least approximately to eliminate, consists in that the equalizing current in relation to the load current and thus the influence of changing phase positions makes small. You may then take one under low load or when idling slightly longer arc in purchase, but because of its lower power (when idling if only the equalizing current is switched), the result is less contact wear.

Further means to the operation of the control device according to the invention of the size of the To make the power factor independent, for example, consist in the division of the switching system in two changeover switches, their energy storage devices clamped together, but one after the other by two control modules and two trigger parts are controlled; if necessary, one can of the moving switch parts control a changeover switch, the excitation of the control part by disconnecting from the just switched Circuit transfers to the circuit, which is now to be switched according to the sequence is. In this way, any number of circuits can be switched one after the other from a single control relay.

In Figs. 3 a and 3 b, a switching system with two changeover switches and two control relays is shown, in which the circuit has the required independence from the power factor. There are two step selectors 20 and 21 are provided, which are either switched through on two parallel contact paths can be or grind, with each winding tapping on each contact path a fixed contact is connected. The switching system can also be used with step selectors, one contact track with the even-numbered ones and the other contact track with the odd-numbered ones Taps of the control winding connected

who are. The switches are labeled 22 and 23. In the circuit according to FIG. 3 a, the load line 24 is connected to the tap selector 20. If you want to switch from one level to the next, the load switch is used first 22 transferred, depending on the load current. The one that triggers this switching movement The control relay is connected to the current transformer winding 2> This switchover position is shown in Fig. 3b. The switch 22 has switched the load current from stage 20 to stage 21. Here the step equalization current closes via the left resistor 26, the changeover switch 23 and changeover switch 22. This equalizing current controls the second relay connected to the current transformer 27, so that the switch 23 is also switched over. It is recommended that all of the To dimension contacts for the full switching capacity and to provide the mechanical drive in such a way that) the control relays can fail at any time and the switching process can still function properly is guaranteed.

Another switching option is shown in FIGS. 4 a and 4 b. The two switches 22 and 23 are connected on the one hand to the load line 24, on the other hand their changeover contacts with one level selector directly and with the second level selector via transition resistors tied together. If from the basic position shown in Fig. 4 a, in which the stage 20 is connected to the load line 24, must be switched over to the stage 21, the switch 22 is first slowly or abruptly switched to the contact connected to the other tap selector via resistor 26, see above that the switching position Fig. 4b results. The contact 22 was hereby connected to the current transformer 25 connected control relays controlled. It was through him when switching the load current switched off. This is taken over by the switch 23 via a resistor. Furthermore, in the position shown in FIG. 4b, the equalizing current is switched on by the changeover switch 22. After the switch 23 through the control relay connected to the current transformer 27 to the Stage 21 was turned over shortly afterwards, the now currentless and located at stage 20 can Level selector can be switched to the next level 21.

Another switching system in which the method according to the invention is advantageously used finds is shown in Figures 5a to 5g.

• The two step switches 30 and 31 are open different taps. The changeover switch 32 first closes the load line 33 to the tap selector 30 at. The second changeover switch 34 is connected to the same tap selector. The that Control relay feeding current transformer 35 is placed in the train of the load line at a point that during the override is also traversed by the step equalizing current.

Instead of a current transformer, a low-ohmic one can of course also be used for the present purpose Use a resistor to which the control relay winding is shunted.

To switch the load line 33 from the step selector 30 to the step selector 31, the first Changeover switch 34 placed on the step selector 31. Now is superimposed on the load current indicated by the solid arrow with a dashed line Compensating current indicated by the arrow. This is caused by the circuit in the switch 34 Switching resistance 36 or limited by a switching throttle. The switches are up now in the position Fig. S b. That of the sum of the equalizing current and the load current fed control relay responds and triggers the changeover switch 32, so that this one according to FIG. 5 c Part of the load current and the equalizing current switches off. If the changeover switch 32 in Fig. 5 d has reached the position shown, the step selector 31 takes over the load. The level selector 30 is thus de-energized again and can be switched on. Should be from level 31 to level 30 are switched back, as indicated in Fig. 5e, the changeover switch 34 is switched back first. Now superimposed on the load current in the circuit of the switch 32 is an opposite directed equalizing current. In FIG. 5 f, the point in time at which the changeover switch 32 is switched over is shown. The load current flows for a short time only through the resistor 36 until that shown in FIG. 5g Position of the switch 32 is reached. This switching system still has the disadvantage that first the equalizing current must be switched on so that the control relay receives the through the The sum of the equalizing current and the load current exceeds the given response limit. The switching process so again cannot run immediately in one go. To now this delay to avoid and to achieve an unstoppable through-connection of switches 32 and 34, it is advantageous to give the control relay two windings, as shown in FIG.

The additional winding 42 is fed by a current that is derived from the step voltage or from a fraction of the step voltage and auxiliary resistances (active and reactive resistances) 44 is won. Its size is set so that this auxiliary current has an effect on the relay system corresponds to the equalizing current in terms of size and phase position. One switch 47 simultaneously switches the load current or part of the load current flowing through it Winding 43 and the auxiliary winding 42 a when the switches 34 and 32 switched in positive sequence should be. The switch 47 can be operated, for example, from the trigger cam of the energy storage drive be operated. By addressing the armature 45, the additional on the Trigger armature 46 actuated force, so that the trigger part 46 in the current zero passage geometric sum of load current and compensation current in the windings 42 and 43 drops. Since only the ampere turns ratio of the two windings for the correct mode of operation

42 and 43 of the control relay is decisive, the Resistor 44 can of course be made much smaller than the transition resistor itself. In the switching process according to FIGS. 7 a to 7 k, no diverter switches are required. It will only a single pole circuit breaker is required to switch it on and off. Such a switching method can be realized particularly well by electromagnetically operated switches, at which the solenoid advantageously depends on the step voltage or the compensating current itself is operated. The two step selectors 51 and 52 are in the circuit of FIG. 7 a on the same Step. The load current is distributed over the two switches 53 and 54 and flows through the circuit breaker 55 into the load line 56. The direction of the current is used as the direction of the pulled out Arrow accepted. Contacts 57 and 58 are used for switching to the next level the switches 53 and 54 are open, so that the circuit shown in FIG. 7b now results. Of the Step selector 52 is de-energized and can go to the next step through the switchover position Fig. 7c Fig. 7 d are switched. When the step selector 52 hits the next step, it switches the Equalizing current on. This should have the direction indicated by the dashed arrow. He is therefore in the same direction as the load current and flows through the transition resistor 59 to the control winding return. Now, as indicated in Fig. 7e, the off switch 55 is opened, namely it is triggered by the control relay according to the invention. Then the load current flows from stage 52 via the switch 54 and the transition resistor 59 into the load line 56. The tap selector 51 is thus de-energized, so that it is connected to the neighboring Level can be readjusted, as Fig. 7 f indicates. The switches 53 and 54 are back in returned to the starting position shown in FIG. 7 a. The off switch 55 is closed again, so that there is now the switch position 7 g. In the same way, the other stages are switched through. When switching back in the opposite direction, first the switches 53 and 54 are brought into the position shown in FIG. 7h. The step selector 51 can be switched to the previous stage without current. It switches the step compensation current one, which is superimposed on the load current in the opposite direction in switch 55 (cf. Fig. 71). The equalizing current is switched off by opening the switch 55 (FIG. 7 k), so that the step selector 52 is also de-energized and the step selector 51 can be connected downstream, whereupon the switches 53 and 54 and the off switch 55 are closed again, so that the basic position (Fig. 7 a) results. The control relay is also connected to the load circuit via a current transformer 60 coupled, which is in the line of the switch 55.

In order to save switching resistances, switching from one stage to the other can also be achieved with a switch, the schematic representation of which is shown in FIG. The control winding 70 provided with taps is connected to the fixed step contact track 71. The movable tap selector contacts 72 and 73 can be connected to the changeover switch contacts 75 and 76 via sliding rails 74, for example. The load line JJ is also connected to the changeover switch, which contains the trigger 78 for the control relay, which the changeover switch 79, whose movable contacts are firmly coupled to one another with a rod or a joint 80, from contact 75 to contact 76 and vice versa depending on The instantaneous value of the load current switches.

In the switching position shown in FIG. 8, the step selector 73 was advanced on the step contact path 71 without current. If the load line Jj is to be switched from the step selector 72 to the step selector 73, the control relay, which is fed by the load current via the shunt resistor or converter 78, is switched on. In the current zero passage or shortly before the current zero passage, the changeover switch 79 then switches from contact 75 to contact 76 with practically no current. Its switching speed is measured or the contact is broken at such an instantaneous value of the current curve that no significant arc occurs and that when the voltage maximum occurs, the moving contact is so far away from the stationary mating contact that the mains voltage can no longer break through this distance . Before the load current to be switched has reached a significant size or as long as the size of the load current is still in the range of the current zero crossing, the changeover switch 79 already switches on the next stage. In the exemplary embodiment shown in FIG. 8, the changeover switch 79 thus already meets the changeover switch countercontact 76 before the load current has reached a significant level.

It has been found that the most advantageous solution basically results when one Switching processes used in which only one shutdown occurs. It is always the load current to switch with the superimposed equalizing current. Since the equalizing current only in the course the switching process occurs, it is advisable to use the two currents, load current and equalizing current, to be superimposed in the control relay before switching over, d. H. an auxiliary current must be formed in this way that the superimposition coil of the control relay already before the switching process takes place, with one of the equalizing current in effect, d. H. appropriate in size and phase Current is excited.

The boiler containing the switch controlled according to the invention can be with pressurized gas or with be filled with oil. In the first case, if an arc occurs, i. H. if the control relay fails, If an overpressure occurs, this actuates signaling or monitoring devices. At in oil boilers switches used (load switches or under

Load to be switched tap selector) can develop in malfunctions due to the switching arcs Throttle trigger a known float relay that actuates signaling devices or controls the switch drive in such a way that the switch switches over without a control relay performs. Known baffle flaps which respond to the flow of oil can also have such control or Operate signal circuits. If the

ίο switch boiler is at operating potential, recommends it is, from the mentioned response organs (exhaust flap, stowage flap or float) falling weights or spring-loaded or driven by other energy storage bodies to trigger the only in turn actuate contact organs for low voltage leading control circuits, which of the Parts carrying high voltage have such an insulating distance that the passage of high voltage in the signal and control circuits is excluded.

Claims (19)

PATENT CLAIMS: 1. Load switch arrangement for step control devices of transformers, chokes or capacitors, consisting of one or more expediently driven by energy storage Circuit breakers, switching resistors or chokes and control relays, characterized in that at least the switch-off moment the switch subjected to greater switching loads by one of the instantaneous values of the step voltage or the switching current affected relay is determined and that the individual components of this Switch, e.g. B. the length of the contact lever, the translation of the gear, the springs and the Shape of the contacts, adjusted and possibly adjustable in such a way that the of the Impulse transmission by the relay until contact separation elapsed in a given time fixed or adjustable ratio to the period of oscillation of the current to be switched. 2. Arrangement according to claim 1, characterized in that that the contact separation at the switch at a specific or adjustable instant before the zero crossing of the switching current he follows. 3. Arrangement according to claim 1 and 2, characterized in that the relay at one given and advantageously adjustable instantaneous value, e.g. B. at the zero crossing of the relay current, actuates a release part, which in turn only controls the drive of the switch or triggers. 4. Arrangement according to claim 1 to 3, characterized in that a polarized relay is used Relay is used whose armature is a DC excited or a permanent magnet, which triggers the switching movement when responding. 5. Arrangement according to claim 1 to 4, characterized characterized in that the control relay has two armatures, the first of which the armature Directional bias of the second armature controls the contact movement by responding is triggered. 6. Arrangement according to claim 5, characterized in that the first anchor when responding the direct current excitation of a winding that additionally magnetizes the second armature with the directional field is switched on. 7. Arrangement according to claim 5, characterized in that the first anchor when responding brings a permanent magnet to the second armature. 8. Arrangement according to claim 5 to 7, characterized characterized in that the first armature actuates a magnetic shutter when responding, which is the directional magnetic field of a permanent magnet or a DC coil shields against the second anchor in whole or in part. 9. Arrangement according to claim 5 to 8, characterized in that the excitation winding of the first armature is excited by the same voltage source as the one to be switched off Current drives, and that the excitation is switched on when the switch drive is switched on is switched on or is switched on with energy storage drive when the energy storage device is charged is. 10. Arrangement according to claim 5 to 9, characterized characterized in that the second armature directs the contact movement to magnetic or electrically controls. 11. Arrangement according to claim 5 to 10, characterized characterized in that the second armature switches the control switch contacts abruptly Lift mechanism triggers mechanically or electrically. 12. The arrangement according to claim 1 to 11, characterized in that the energy storage elevator a control relay switching contact, the drive of which is coupled to that of the energy storage elevator, is closed after charging is complete. 13. Arrangement according to claim 1 to 12, characterized characterized in that to keep constant the proper time of the switch and the drive Contacts large centrifugal masses or spring forces are effective in the engine, so that the Friction of the gear parts and the friction of the contacts are negligibly small. 14. Arrangement according to claim 1 to 13, characterized characterized in that two load switches and two control relays are provided for switching of which one only controls the load current after being triggered by the one control relay of one step transfers to the next step, while the other is triggered by the second relay takes place a little later, only the equalizing current damped by the resistor and switches part of the load current. 15. Arrangement according to claim 1 to 14, characterized marked that besides the two Step switches two changeover switches are provided, the first of which crosses the load line a supersonic resistor switches from one level to the other and only the equalizing current switches on, while the second switches on the load current and the equalizing current when the load line is switched from one level to the next switches, and that of the sum of the two currents only one control relay is energized ίο which controls the second changeover switch. 16. The arrangement according to claim ι to 15, characterized characterized in that the control relay has two windings, one of which is from the Load current and the second of a corresponding to the compensation current of the phase position proportional current is excited and causes the entire switching process to proceed. 17. Arrangement according to claim 16, characterized characterized in that the current direction in a ao of the two excitation windings of the control relay depending on the control direction (direction of movement of the step selector) is reversible. 18. Arrangement according to claim 1 to 17, characterized characterized in that the switch-on processes are transferred to the tap selector, but the switch-off processes of special ones Off or changeover switches are made, with the control relay in the circuit of the off or Switch is located. 19. Arrangement according to claim 1 to 18, characterized characterized in that in the switch tank or in the supply line to the expansion vessel a float arrangement which is known per se and which responds to the evolution of gas or oil flow or a damper or an exhaust valve actuated by gas pressure is provided, the signaling devices or control circuits for switching off the switch drive or for Switching through the malfunctioning switch mechanism actuated. For this purpose 2 sheets of drawings 1 9550 9.54