DE892181C - Step control device for transformers or resistors operated synchronously in dependence on the voltage or the current, working under load - Google Patents

Description

Actuated synchronously depending on the voltage or the current, Step control device for transformers or resistors working under load In the case of alternating current switches, this can significantly reduce the power to be switched off that the switch-off time can be set using synchronously operating switching means sets in or shortly before the zero crossing point of the current to be switched off. With advantage According to an older proposal, this synchronous circuit can also be applied to step control devices for transformers or resistors, where during a control step unstoppable by an energy store triggered by the synchronous switching means in a known manner from one main contact via connected to balancing resistors Intermediate contacts are switched through to another main contact. In such Control devices are known to require two shutdowns for each control step, now when the switching device is synchronized at a precisely defined time interval successive and precisely matched to the zero crossings of the currents to be switched off must be. With the correct setting, such synchronously actuated step control devices work flawless, but undesirable effects occur over time as a result of contact erosion Shifts in the switch-off times compared to the phase of the switch-off Currents on. The contact opening is getting premature more and more, so it is getting further and further ahead relocated the zero crossing of the current to be switched off. This will turn off the Performance increases with the consequence that the contacts wear out more quickly, the switching oil soot more quickly and the performance of the switch deteriorates.

The invention has the task of eliminating these deficiencies. According to the invention the step control device is designed in such a way that the contact erosion causes the Shifting of the points in time of the disconnection at the load switch automatically compensates. For automatic compensation, the synchronously working One part of the triggering devices actuated by switching means is made of a material, which wears out to such an extent that that caused by this wear and tear Delay in triggering time just the effect of contact erosion compensates for the position of the switch-off time. It can also be used for automatic compensation generated by .the switching operations of the circuit breaker, such as the contact erosion corresponding, z. B. amount of gas collected in a bell and one in the load switch oil and damping vanes that work in the gas flow and are attached to the movable circuit breaker part serve, or the load switch contacts exposed to the burn can be used as rolling contacts formed and each composed of two materials of different thermal expansion be that due to the heat generated during the burn-off, the contacts in the Sense of the compensation of the burn occurs.

The invention is explained in more detail with reference to the drawing.

The winding i is provided with several taps 2, 3, at (which in a known manner, the step selector 4, 5 alternately switched along without current will. The step selector 4 is connected to the main contact 6 and via the transition resistor 7 connected to auxiliary contact 8. The step selector 5 is with the main contact g and connected to the auxiliary contact i i via the resistor io. 12 is the movable one Switching contact whose knee joint 13 has an angle lever. 14 of one with one Link 15 provided slide 16 -actuated. The slide can be in the end positions be locked by pawls 17, 18. _ The pawls are operated by a plunger ig disengaged, ider on a second slide 21 operated by a crank 2o is attached. The force storage spring 22 is arranged between the slides 16, 21. The crank 2o is via a gear 23 which also switches the step selectors 4, 5 a synchronous motor 24 or a synchronous motor in the time range of the latch release switched asynchronous motor.

The device works as follows: During the movement in the direction of the arrow drawn prior to the position shown of the slide 21, the force storage spring 22 is tensioned. If the slide 21 now moves further to the left under the action of the crank 2o, the pawl 17 is disengaged. Under the action of the spring 22, the slide 16 swings inexorably in the direction of the arrow to the other end position in which it is locked by the pawl 18. During this oscillating movement, the contact 12 is transferred from the main contact 6 via the auxiliary contacts 8, ii to the main contact g via the parts 1 5, 14, 13. Initially, contacts 6 and 8 are bridged. When this bridging is canceled in the further course, a first shutdown process occurs. The load current at contact 6 must be switched off. Then the contacts 8 and ii turn bridged. When the bridging is canceled, there is a second shutdown process. The current to be switched off is made up of half the load current and the equalizing current. According to an earlier proposal, the release time of the pawl 17 is now set in relation to the phase of the three-phase voltage system feeding the synchronous motor 24, and furthermore, the contact spacings are so adjusted and the driving and damping forces as well as the inertia forces of the switch are so coordinated, that the switch-off times in the two switch-off processes are shortly before the zero crossing of the current to be switched off.

This is explained in FIG. 2 with the aid of a diagram for the first shutdown process. For the sake of simplicity, it is assumed that the release time for the pawl 17 is only about half a wave before the switch-off time. In fact, because of the great inertia of the switch, there will be several such half-waves in between. On the one hand, the time t and, below that, the switching travel s is plotted as the abscissa. 6 is the contact provided with the same reference number in FIG. Triggering takes place at time t1. At this point in time, the current J to be switched off by the contact 6, which is entered as a sine curve in FIG. 2, has a certain instantaneous value. As a result of the special adjustment of the switch, the contact 12 leaves the contact 6 at time t2, ie at or shortly before the zero crossing of the current J to be switched off. A very specific time span a lies between times t1, t2. If contact 6 burns more and more in the course of operation, then 6o gradually moves in the path diagram on the left, for example its switch-off to point 61. The contact separation then no longer takes place during or shortly before the zero crossing t2 of the current to be switched off, but earlier, at the point in time t., at which the current J still has a certain instantaneous value. This increases the power to be switched off and the contact is more stressed. In order to move the switch-off point as possible in or shortly before the zero-crossing point of the current to be switched off, the release parts, e.g. B. the pawls. 17 and 18, on the parts decisive for the phase position of the triggering time, e.g. B. at 170 and 18o, made of a material that wears to such a degree that the delay 4t of the release time caused by wear and tear compensates for the effect of the contact erosion As on the timing of the switch-off time. After a long period of operation, for example, tripping does not occur until time t4, and the distance ti, t3 is equal to the distance t4, t2, so that the switch-off time coincides again with the zero crossing of the current I despite the contact erosion. Corresponding considerations apply to the second switch-off process, that is to say for the moment in which the bridging of contacts 8 and ii is canceled.

Possible further corrections of the displacements caused by contact wear the switch-off times can be determined by changing the switching speed as a function of .the number of switching operations carried out. So you can z. B. by means of a transmission with a high transmission ratio driven by the motor 24 slowly gradually the tension of the force storage spring 22 or other that Adjust the forces influencing the switching speed. So you can z. Belly the damping forces acting on the gearbox as the operating time progresses change, as shown in FIG. 3, for example.

Here is a schematic of the widely known circuit breaker with a knee joint polygon shown for regulating transformers, its design and mode of operation not detailed should be explained. The middle knee joint -25 is in a known manner provided with a damping wing 26, which when switching over to the dashed line Position 26o oscillates and reduces the switching speed. The one from the damping wing 26 painted space is arranged in a collecting bell 27, which the contact erosion catches evolved gas. The further the contact erosion progresses, the more so the switching oil is displaced from the bell 27 by the accumulated gas and around the further the damping flight 126 emerges from the switching oil, the less it becomes the damping force, so that the switching speed during operation grows. By correct matching of the volume of the bell 27 and the spatial arrangement of the damping vane 26 can be a depending on a specific schedule Switching speed that changes from contact wear for longer operating times determine. Together with the measures shown in FIG. 2, one is in the Position, the influence of the contact erosion on the position of the for both shutdown processes Compensate for switch-off times. In a corresponding manner, others can work for the Switching speed, decisive forces, masses or damping depending on from contact wear or from the number of switching operations carried out for the purpose of compensation the contact wear can be changed.

Likewise, one can also influence the influence by shifting the contacts of the burn-up to the switch-off times. So you could z. B. the contacts thanks to a gearbox with a large transmission ratio and a ratchet mechanism, that the alternating direction of rotation of the motor 24 in a constant direction of rotation toggles, swivel. Furthermore, it would also be possible to use one or the other of the To swivel contacts slowly according to the burn.

A particularly simple way of compensating for the influence of the ILontaktabbran.des on the switch-off times is shown in so-called rolling contacts in Fig. Q. and 5. In FIG. 4, part of a circuit breaker with a knee joint polygon and rolling contacts is shown. Here the movable contact rolls on the contact 8 when switching off, for example, the current consisting of half the load current and the equalizing current. It gradually changes from the position 130 shown with solid lines into the position 130a shown with dashed lines. Here, too, there is a shift in the switch-off time with increasing contact wear. However, if contacts 130 and 8 are made of two materials with different thermal expansion, e.g. B. made of tungsten and copper, in such a sequence that the contacts gradually bend under the heat effect of the arc from the dashed shape shown in Fig. 5 into the shape indicated with solid lines, balanced, so that the switch-off time remains in the same place.

The last measure is particularly suitable for control devices for high currents. The influence of room temperature on the viscosity of the load switch oil and thus on .the damping of the switching speed can: be compensated by artificial heating of this oil by z. B. keeps the 01 permanently at a temperature of .Io ° C by a controlled heater.

The invention is for alternating currents of normal frequency and for such of railway frequency usable with success. It has the advantage that the synchronous Switching device still works properly even after prolonged operation, because the Influence of the contact erosion on the switch-off times is compensated.

Claims (4)

PATENT CLAIMS: i. Synchronously in dependence on the voltage or current operated, operating under load tap controller for transformers and resistors, characterized in that it is designed such that the (by the contact erosion (A, Fig. 2) shift occurring at the circuit breaker of the instants shift from t2 to t3, Fig. 2) automatically compensates for the contact separation. 2. Step control device according to claim i, characterized in that for the automatic compensation of the shifting of the times of contact separation occurring at the load switch, the triggering devices operated by the synchronously operating switching means (z. B. 17 and 18, Fig. I) on their one part (z B. at 170 and i80, Fig. I) consist of a @Nrerkstoff that is to such an extent. wears out so that the delay (dt) of the discharge time caused by this wear and tear just compensates for the effect (of the contact erosion (As) on the position of the switch-off time. 3. Step control device according to claim i, characterized in that to automatically compensate for the shift in time that occurs at the load switch the contact separation generated by the switching operations of the load switch, for example the - contact wear corresponding, z. B. caught in a bell (27, Fig. 3) Amount of gas as well as one working in the load switch and in the amount of gas, on the moving Load switch part fastened - damping wings (26) are used. 4. Step control device according to claim i, characterized in that for automatic compensation of the am Load switch occurring shifting the times of contact separation the dem Load switch contacts exposed to fire as rolling contacts (13o and 8, Fig. 4 and 5) are formed and each (13o or 8) so made of two different materials Thermal expansion is made up of that by the heat occurring in the Abbranid the contacts are discarded in order to compensate for the burn-off.