DE1184003B - Variable transformer with two-speed adjusting winding that is polished on the contact track - Google Patents

Description

Stelltransformafor with two-thread, polished on the contact track Actuating winding To regulate voltages under load with smaller powers mostly variable transformers with a single start winding are used, on which they are bare Control winding from turn to turn a current collector is guided along which consists of a resistance material, preferably carbon, which is used in the short-circuit current within moderate limits holds. The power limit of these coal roller variable transformers is due to the resistance the carbon roll and the resulting limitation of winding voltage and mains current given. In order to be able to advance into higher performance areas, one has instead of the Carbon roller also has two metal switch pins connected to one another via a resistor used, which are progressively led alternately from turn to turn. Here is the limiting function otherwise assumed by the coal roller for the Winding short-circuit current in the transition resistor placed between the switching pins has been relocated. It is true that such an arrangement has to cope with greater performance. However, the switching pins must each switch the winding power, which is higher In the long run leads to an intolerable burn-up. You already have this avoided by interposing transformers in the supply lines has placed contactor contacts to the switching pins so that the switching pins are de-energized put on and take off. The control winding must be made very precisely and every turn be specially processed for the engagement of the switch pins. Besides, it's a complicated one Mechanics are required to ensure that the switch pins are exactly in the middle place on the turns and do not get into a position between two turns, where they would cause a full turn short circuit.

I There are also variable transformers with double-start winding became known, in which such winding short-circuits cannot occur, if the metallic pantograph touches two adjacent turns at the same time, because the two intertwined windings are not directly, but via current-limiting ones Funds are allied with one another. For example, the two are intertwined Control windings of these known transformers via a resistor or a Choke coil connected to one another, in the middle of which the consumer is connected is the one with its other terminal on the pantograph sliding on the control winding lies. The two control windings are already through flux displacement transformers have been connected to each other. The flow displacement when switching over the pantograph one has already let go of the regulating transformer itself .. With all of them However, these known arrangements with two or more start winding must the pantograph itself when switching from one turn to the next Switch power by which = the consumer power in this switching step changes. At higher currents this leads to the destruction of the in the long run Pantograph.

Arrangements for regulating voltages are also part of the stand technology, in which the total effective magnetic flux is constantly changing is: This is both for step-by-step transformers and for rotary transformers that no longer have a pantograph, as is also the case with standing transformers, where the pantograph is in a helical path around the winding lug @ is guided along the winding wire, with a connecting wire passing through a gap moved in the core, so that the included flux can be continuously changed without switching operations kantiz These constructions require a great deal of mechanical effort.

Finally, there are so-called tapping or Stufentränsformatoreri well known, in which the desired winding tapping is used with de-energized selector contacts or level selected and then the power in so-called load switches from one Dial-up contact is switched to the other. These step transformers have catchy windings, which are provided with taps, which are separated into one arranged contact track out are attacked by the dial-up contacts. The load switch contains switchover resistors that switch over an uninterruptible switch enable. Instead of the switching resistors, there are also reactors and Instead of load switches with switching resistors, also through direct current bias adjustable choke coils have been used. The effort for this is only worthwhile for large ones Services.

The invention is based on the in the A b b. 1 and 2, the reference numerals of which match, described embodiment shown. It relates to a variable transformer with a core 1, a primary winding 2, which can also be arranged as a thrust winding within the adjusting winding 3, 4 to linearize the voltage curve of the variable transformer, and with a two-speed adjusting winding 3, 4 that is blank on the contact track, in which the one consumer connection with a single pantograph 6 which can be moved by a motor along the control winding 3, 4, the other consumer connection is connected to the ends of the two control windings wound into one another. It consists in the fact that two mutually interlocked switches 8, 9 are located in the two feed lines to the control winding ends, which automatically transfer the consumer current from one to the other control winding 3, 4 when the current collector 6 is switched from one to the other control winding 3, 4 overturn, the contact established by the current collector 6 between the two control windings 3, 4 being used as the criterion for switching over. Because the two mutually interlocked switches 8, 9 overturn the load at the moment the current collector is switched over, the current collector 6 is de-energized. It goes without saying that it carries the load current continuously. However, no spark can arise during the switching operation because this takes place in the switches 8, 9. The current collector 6 is therefore not subject to any wear. Ohmic switching resistors are not available. The control winding is easy to manufacture. There are no special mechanical conditions to be met because the switchover is triggered by the pantograph itself or by the contact between the two control windings 3, 4 that it establishes.

According to the invention, the contact established by the current collector 6 between the two actuating windings 3, 4 at the moment of switching over is determined in that two relays 13, 14 are connected in series to the voltage of the last turn at the free end of one actuating winding 4 , possibly via a rectifier. the common connection of which is led to the free end of the other actuating winding 3. When the current collector 6 is switched over, one of the relays 13, 14 is short-circuited by the current collector 6 and therefore drops out. It is used in the manner described below to switch the load from one control winding to the other.

In a further embodiment of the invention, an iron-closed divider choke 5 with a center tap, to which the one switch 8 is connected, is connected to the voltage of the first turn of the control winding 3. This ensures that the steep steps are symmetrical and each amount to half a winding voltage. The divider choke5 is to be designed so that its saturation voltage is greater than the winding voltage of the variable transformer. Your winding only needs to be designed for a little more than half the nominal current strength, because in it a current split occurs almost in a ratio of 1: 1, provided that the total voltage taken for the consumer 7 is at least several winding voltages.

The first turn of the actuating winding 3 can be carried out in a manner known per se also be passed through a hole in the core 1 and encompass half the river. Also because of that it is achieved that the setting steps are symmetrical and each half a winding voltage be.

The first turn of the control winding 4 is connected directly to the consumer 7 via the switch 9.

The variable transformer according to the invention also contains a time switch device 17, 18, 19, 20, which is started at the moment when the current collector 6 is switched over by one of the relays 13, 14 and the self-holding of the motor contactors 15, 16 belonging to the motorized adjustment device for a short time interrupts so delayed that the current collector 6 comes to a standstill in the middle of the next turn, provided that no control command is pending. The capacitor 19 of the timer is designed with respect to the properties of the relay 17 so that the interruption of the self-holding of the motor contactors 15, 16 called forth by the contacts 17a, 17b in a moment just before the current collector 6 reaches the middle of a turn of the Control winding has reached takes place. The overrun of the servomotor 12 is taken into account so that the current collector 6 comes to a stop in the middle of the turn. The current collector 6 is thus synchronized by itself to the control winding without the need for a particularly precise mechanical processing of the standing winding 3, 4 or a mechanical coordination of the transport steps with the turns of the standing winding.

In order to delay the reactivation of the direct current relay 17 somewhat and thus give the motor contactor 15 or 16 the opportunity to safely drop out, the direct current relay 20 can also be equipped with a damping winding, not shown, so that the auxiliary voltage for the direct current relay 17 is switched on again with a delay .

Furthermore, a self-starting circuit is provided according to the invention, which consists of an auxiliary contact 13 d, 14 d each of the relays 13, 14 and which allows the motor contactor 16 intended for the downward direction to attract automatically when the current collector 6 is on two turns at the same time without one of the Motor contactors 15, 16 is tightened.

If the two internally wound control windings 3, 4 are designed to be equally strong, the type output is lower by a factor of 1l r3 than the type output would be of an equally large single-start control winding with the same total copper weight. According to the invention, this power ratio can be improved by designing the two adjusting windings 3, 4 , which are wound into one another, with different copper cross-sections. For example, a profile copper of the same height but different thickness can be selected for both control windings. Then, however, it must be ensured by switching measures that the current collector 6 can always stop only on the stronger standing winding and the weaker actuating winding is only used briefly when switching over. This can be achieved in a further embodiment of the invention that the time constant of the time switching device 17, 18, 19, 20 started at the moment of the first switching over is selected so that the self-holding of the motor contactors 15, 16 is interrupted for a short time at such a moment that the current collector 6 comes to a stop only in the middle of the next but one turn. A further self-starting circuit, which contains the auxiliary contacts 10x, 10 y, 11 x and is shown in dashed lines, also ensures that the motor contactor 16 intended for the downward direction always picks up automatically when the switch assigned to the control winding with the smaller cross section 3 8 is closed and the motor contactor 15 intended for the upward direction has dropped out. This self-starting device prevents the current collector from stopping on a turn 3 with a smaller cross-section.

With these measures, the type output of the two-start actuating winding 3, 4 are largely approximated to that of a single-thread actuating winding.

The switches 8, 9 in A b b. 1 are shown as mutually interlocked mechanical switches, are advantageously, as in A b b. 2, designed as iron-closed switching inductors 8, 9 , the secondary windings of which are alternately short-circuited by two load contactors 10, 11. This arrangement has the advantage over mechanical switches that it works without a galvanic interruption in the circuit of the consumer 7. It is important that the switching chokes 8, 9 are switched alternately so that the secondary winding of the choke acting as a closed switch is always opened first before the secondary winding of the other choke coil is closed. This is brought about by the auxiliary contact 10 a of the load contactor 10, which transfers the load at the moment the current collector 6 is switched over from one steep winding to the other steep winding. At the moment of switching over, when the auxiliary contact 10a is in the middle between its two rest positions, both choke coils 8, 9 are open on the secondary side. They are then driven into saturation by the load current so that there is still no current interruption. In addition, the choice of the transmission ratios between the primary and secondary windings of the switching inductor coils 8, 9 enables the current levels to be switched by the load contactors 10, 11 to be transformed down to manageable values compared to the current flowing in the consumer 7, with the switching voltage naturally increasing accordingly.

The load contactor 11 is used to take into account the direction of travel of the pantograph 6 when switching the load.

The switching inductors 8, 9 are to be designed so that their saturation voltage possibly greater than the sum of all in the feed circuit for the consumer 7 occurring voltage drops. In addition, the saturation voltage of the switching reactors 8, 9 must be at least as large as half the winding voltage, because the blocked Switching throttle, when the other is open, at the moment the Current collector 6 gets the voltage lying above half the divider choke5.

Provided the two stall windings 3, 4 with different cross-sections are executed, the two switching throttles 8, 9 in be interpreted differently in a corresponding manner.

Instead of the one provided with contacts. Switching elements can after the invention also contactless switching elements, such as amplifier tubes, transistors, Thyratrons with hot or cold cathode, semiconductors with thyratron-like properties, other semiconductor switching elements or transducers are used and for the purpose Shortening the switching times and increasing operational reliability, especially the Switching tasks of the relays 13, 14 and the load contactors 10, 11 in whole or in part take over. The shortening of the switching times allows, in particular, a higher actuating speed of the pantograph 6 too. This adjusting speed is limited by the fact that the Load contactors 10, 11 need a certain time to switch. During this time the contact that the current collector 6 makes between the control windings 3, 4 must be . remain because the pantograph 6 would otherwise draw a switching spark. When using normal contactors, this is only possible at relatively low actuating speeds guaranteed.

Since the entire arrangement can not work without auxiliary voltage and the current collector 6 does not function during its movement along the actuating winding 3, 4 the circuit arrangement would soon be destroyed, it is necessary that the auxiliary voltage for the adjustment device and the switching elements in front of the power contacts, one Main contactor 23 is taken from the same network, eia which the variable transformer connected. The same auxiliary voltage should also be used to supply the coil of the main contactor 23 are used. Then it is inevitable with every failure of the auxiliary voltage the variable transformer is also disconnected from the mains. The circuit arrangement remains different Functional if the supply voltage for the standing transformer is intentional is switched off.

Claims (12)

PateatansprfChe: 1. Stelltrandormator with two-speed, on the contact track blnukgeät-or Stelklung, in which one Varbkundenanschilluß with a single along the Stellwicldung motor-driven pantograph, the other consumer must be connected to the ends of the two intertwined control windings, characterized in that in the both feed lines to the. SteUwicld.ungsenden two mutually interlocked switches (8, 9) are located, which when the current collector (6) is switched from one to the other self-winding (3, 4) automatically switch over the consumer current from one to the other high-angle winding (3, 4) , whereby the contact between the two control windings (3; 4) established by the current collector (6) is used as the criterion for switching. 2. Standing transformer according to claim 1, characterized in that two relays (13, 14), optionally via rectifier, are connected in series to the voltage of the last turn at the free end of one control winding (4), their common exclusion to the free end the other stall winding (3) is performed. 3. Stall transformer according to claims 1 and / or 2, characterized in that on the voltage decorative first turn of an actuating winding (3) there is an iron-closed divider choke (5) with a center tap, to which the one switch (8) is connected. 4. Variable transformer according to claims 1 and / or 2, characterized in that that in a known manner, the first turn of the steep winding (3) through a Hole in the core (1) is guided and includes half the river. 5. Variable transformer according to claims 1 to 4, characterized in that a time switching device (17, 18, 19, 20) is provided which is started at the moment of tlberschaltens the pantograph (6) by one of the relays (13, 14) and the self-holding of the motor contactors (15, 16) belonging to the motorized adjustment device is interrupted for a short time with such a delay that the current collector (6) comes to a standstill in the middle of the next turn if no steep command is pending. 6. Variable transformer according to claims 1 to 5, characterized in that one of each auxiliary contact (13 d, 14d) of the relays (13, 14) formed self-starting circuit is provided which can automatically attract the motor contactor intended for the downward direction (16) when the current collector (6) is on two turns at the same time without one of the motor contactors (15, 16) being attracted. 7. high-speed transformer according to claims 1 to 6, characterized in that the two high-pitched windings (3, 4) are designed with different copper cross-sections. B. Step-up transformer according to claims 5 and 7, characterized in that the time switch device (17, 18, 19, 20) interrupts the self-holding of the motor contactors (15, 16) for a short time so delayed that the current collector (6) only occurs in the middle of the next but one Turn comes to a standstill. 9. Step-up transformer according to claims 7 and 8, characterized in that a further self-starting circuit formed by auxiliary contacts (10 x, 10 y, 11 x) is provided, which then always allows the motor contactor (16) intended for the downward direction to attract automatically when the switch (8 ) assigned to the vertical winding with the smaller cross section (3) is closed and the motor contactor (15) intended for the upward direction has dropped out. 10. Variable transformer according to claims 1 to 9, characterized in that the switches (8, 9) are designed as iron-closed switching inductors whose secondary windings are alternately short-circuited by two load contactors (10, 11). 11. Variable transformer according to the claims 1 to 10, characterized in that instead of the contact switching elements contactless Switching elements such as amplifier tubes, transistors, thyratrons with warm or cold Cathode, semiconductors with thyratron-like properties, other semiconductor switching elements or transducers are used and for the purpose of shortening the switching times and increasing them the operational safety in particular the switching tasks of the relays (13, 14) and the Load contactors (10, 11) take over in whole or in part. 12. Variable transformer according to claims 1 to 11, characterized in that the auxiliary voltage for the adjusting device and switching elements in front of the power contacts of a main contactor (23) is taken from the same network to which the step-up transformer is connected, and also for the voltage supply of the main contactor (23) serves. In. Documents considered: German Patent No. 918459; Austrian Patent No. 165 807; French Patent No. 1106106; ETZ-A, Volume 77 (1956), Issue 22, pp. 834 to 836; AEG-Mitteilungen 47 (1957), issue 5/6, pp. 136 to 140.