DE1055082B - Arrangement for controlling electromagnetic alternating current synchronous switches - Google Patents

Description

GERMAN

Fast electromagnetic switches, so-called switch cartridges, have been developed for the synchronous switching on and off of alternating currents, especially in rectifier operation. They essentially consist of a magnet system with an armature, which also serves as a current bridge, the circuit being closed by electromagnetic action and usually opened by a spring force counteracting the magnetic forces. It has also been proposed to bring about the opening movement by magnetic forces alone or in conjunction with a spring. Some typical difficulties have now emerged with systems of this type. In order to have sufficient dielectric strength when switched off, a relatively large switching path is desirable. However, since the switch-on time should be short (a few I (H ⁴ S)), this has the disadvantage that the average switch-on speed, especially the impact speed, must be high on the fixed contacts, which leads to strong bouncing and destruction of the contacts Even when it is switched off, it is difficult to brake the armature and to avoid bouncing or swinging back. The large switching travel also has the disadvantage that the pull-in ampere turns must also be large, which leads to unfavorable conditions when the load is small.

It has also been proposed to bring the armature closer to the fixed contacts immediately before closing by pre-exciting the switch-on magnet system with an additional pulse. In this way, the disadvantages mentioned at the outset can be largely eliminated. However, experience has shown that it makes certain difficulties to dose this additional pulse in such a way that the armature actually stops shortly before contact is made and not for example. overshoots; on the other hand, the reverse voltage can be increased significantly, even if only temporarily, by the additional pulse as a result of the transformer coupling.

The invention now relates to an arrangement for controlling electromagnetic alternating current synchronous switches which have at least one armature, an associated current bridge and an on and off magnet system for actuating the armature, the current bridge in its rest position at a predetermined distance of less than 0.1 mm is held by the fixed contacts. A system with such a small contact spacing cannot easily be used for higher and high voltages. It is therefore known that the contacts have been arranged in a vacuum or in a medium of increased dielectric strength. However, this makes the construction of the switching arrangement more complicated and arrangement
to control electromagnetic
AC Synctiron Switch

Applicant:

FKG Fritz Kesselring Gerätebau AG,
Bachtobel, Weinfelden (Switzerland)

Representative: Dipl.-Ing. R. Barckhaus, patent attorney,
Erlangen, Eichenweg 10

Claimed priority:
Switzerland from April 2, 1953

Dr. Fritz Kesselring, Zollikon, Zurich (Switzerland),
has been named as the inventor

prepared especially for large currents due to the gas-tight current inlets and their changes considerable difficulties due to thermal expansion. According to the present invention will have sufficient dielectric strength when operated in ordinary air under atmospheric pressure achieved by a fundamentally different and novel measure.

According to the invention, this occurs at the latest when the reverse voltage is applied by energizing the switch-off magnet system a force acting on the armature in the disconnection direction, which causes the current bridge their position of rest in the mentioned direction exceeds and their distance from the fixed Contacts at least to the same extent as the reverse voltage itself increases.

It is evident that when the contacts are closed there is practically no voltage consists. When switching on, the ratios can easily be made so that the closing of the Contacts are made at low voltage. In the case of rectifiers, this is the aim wherever possible, in particular also to avoid the so-called switch-on migration, which occurs at voltages above about 12 V, to avoid. When switching off, however, occurs

809 790/380

generally a relatively high voltage very soon after the contact has been separated, which never coped with contact distances of 0.1 mm or less in air at atmospheric pressure could be. This is where the fundamentally new insight comes into play, according to which the distance of the Current bridge from the fixed contacts at least as much as the reverse voltage itself increases. Since the breakdown voltage is almost exactly proportional, especially at small distances the distance, such an arrangement can withstand practically any high reverse voltage, without it being necessary to increase the switch-on travel.

Since it is generally expedient that when the reverse voltage occurs' - or, as is the case with switches says the recurring voltage - ■ there is already a certain contact distance, so can it may be useful that the force acting in the disconnection direction has already preceded it by a predetermined time the current zero begins; especially for rectifiers with switching reactors, it is advantageous to λνεηη the force acting in the switch-off direction already becomes effective at the start of the switch-off stage. To a It can be useful to avoid overshooting of the armature in the switch-on or switch-off direction as far as possible be to bring damping means to use, for example by the fact that eddy currents be generated in the armature or in a winding on the armature or that a damping winding on is attached to the switch-off magnet system, whereby a valve can be used to ensure that the attenuation, for example, only in the switch-on direction, d. H. acts with decreasing magnetic flux. In general, it proves to be advantageous to adjust the distance between the fixed and movable Contact in the rest position to values below 0.1 mm, e.g. B. to 0.05 mm, set and the switch-on force to be dosed in such a way that the impact speed on the fixed contact is a maximum of 30 cm / s. This largely prevents bruises and abrasion and keeps noise to a minimum be restricted. Under certain circumstances, it can be advantageous that the anchor, for example, under the Action of a spring rests first on the fixed contacts and then through the premagnetization the switch-off magnet system is brought into its rest position. In this case it is possible bring about the switch-on by weakening the switch-off bias.

In order to increase the fatigue strength of the arrangement, the switch-off magnet system is expediently designed in such a way that that its pole shoes are not touched by the armature even at the highest reverse voltage that occurs will. This measure also makes a significant contribution to reducing the generation of noise.

In the following, the rest position is understood very generally to mean that anchor position which is under the influence of spring forces alone or in conjunction with constant magnetic forces comes about.

The invention is explained in more detail below with reference to the drawing, in which the

Fig. 1 shows an example embodiment according to the invention schematically, while Fig. 2 the up and

Figure 3 shows the side elevation of this arrangement.

In FIG. 1, 1 denotes a three-phase transformer with the windings 2 primarily connected in delta and the secondary windings 7f connected in star

gen 3, 3 ', 3 ". With 4, 4', 4" switching throttles are designated. In the following, only the arrangement belonging to the transformer winding3 will be described, since it corresponds completely to that of the other two phases. The switching inductor 4 consists of an iron core 5 and a main current winding 6. Any bias windings that are unrelated to the invention have been omitted. 7 is the switch; it consists of the current bridge S _j which is held by the spring 9, which in turn on the Isoli he pieces 10 and 11 is attached. 12 and 13 are the fixed contacts, 14 the main current winding, 15 the switch-on winding and 16 the switch-off winding. 17, 18 and 19 are valves, 20 is a connecting line, 21 is a bypass resistor and 22 is the load. Connection points are designated by P, P _v P _2. With reference to Fig. 1, two possible circuits are now to be considered, which are characterized in that the additional winding 16 in one case (circuit I) to the points P and P _v in the other case (circuit II) by means of the line 20 to the Points P ₁ and P _{2 is} connected, the connection at P being broken.

Circuit I. In the de-energized state, ie when the windings 14, 15 and 16 are de-energized, the armature or the current bridge 8 is opened by means of the spring 9 in its relaxed state immediately in front of the stationary contacts, e.g. B. held at a distance of 0.1 ... 0.05 mm and less. In the case of rectifier operation, this should be the case immediately before the switch-on coil 15 is excited. In general, this can also be done safely, since at this time the voltage between the contacts is very low, unless the switch-on is delayed for reasons of voltage regulation. As soon as the switch-on winding 15 conducts current, the armature 8 is attracted, due to the small distance and correspondingly small magnetic air gap even with a very small number of ampere turns of z. B. only 100 AW or less. As soon as the fixed contacts 12 and 13 are connected to one another via the switching bridge 8, the stage caused by the remagnetization of the switching inductor 4 begins to run. The main current then sets in, which, as a result of the excitation of the main current winding 14, leads to an increase in the contact pressure. The main current again approaches its zero value, the armature 8 initially falls under the sole influence of the spring 9 during the Ausschaltstufe the switch inductor from 4, wherein a possible spark formation through the valve is suppressed 18th After the switch-off stage has elapsed, the reverse voltage now appears on contacts 12 and 13 and thus also between points P and P _1. This has the consequence that the winding 16 is excited and therefore the armature 8 is removed from the stationary contacts 12, 13 against the spring force, the higher the blocking voltage. In other words, the contact spacing and thus the electrical strength of the switch automatically adapt to the reverse voltage; the distance is large with a high reverse voltage and small with a low reverse voltage. A particular advantage of the arrangement is that no additional power source is necessary to feed the winding 16, which is generally designed to be of high resistance. From the sequence of the switching process described, it can be seen that, in the case of the circuit I, the acceleration of the current bridge 8 during the switch-off stage is only caused by the spring 9

Claims (9)

1 is effected. This disadvantage is now avoided in circuit II. Circuit II. As already mentioned, it arises from circuit I in that the connection at P is released and the additional coil 16 is connected via a rectifier 19 and line 20 to point P2 . In principle, the switch-on process takes place in exactly the same way1 as it was described for circuit I. When switching off, however, the coil 16 is already excited when the switch-off stage starts. The consequence of this is that the armature 8 is accelerated in the disconnection direction by the magnetic force generated by the winding 16, in addition to the spring 9, so that after the disconnection stage has elapsed, a large contact distance is already achieved and thus a correspondingly high level of security Backfire exists. 2 and 3, an embodiment of such a switch is shown in elevation and side elevation. Therein 30 and 31 denote the fixed contacts, 32 the armature with the current bridge 33 (see FIG. 3) and the short-circuit winding 34. 35 is a leaf spring to which the armature 32 is attached. In turn, it is screwed tightly to the insulating pieces 36 and 37. 38 and 39 are magnet yokes which are separated from one another by an insulation 40. They open at the top into the pole pieces 41, 41 a and 42, 42 a, which are attached to the stationary contacts 30 and 31 with the aid of the rivets 43 and 44. 45 is the main current winding, 46 is the switch-on winding, 47 and 48 are the connections. Above the armature 32 there is a switch-off magnet system, consisting of the U-shaped yoke 49 with the pole pieces 50 and 51, the switch-off winding 52 and the additional winding 53. 54 is a valve, 55 is a permanent magnet, with which a constant pre-excitation of the switch-on magnet system 38, 39 can be generated. It can be seen that when the windings 45 and 46 are excited, the armature 32 is moved downward, the stationary contacts 30 and 31 being connected to one another via the current bridge 33. When the switch-off winding 52 is not energized, the distance between the current bridge 33 and the stationary contacts 30 and 31 should expediently be at most 0.1 mm, so that with a low mean switch-on speed of, for example, only 30 cm / s, it is still possible to switch on at times that are significantly smaller than 1 millisecond. If, however, the coil 52, which, as was shown with reference to FIG. 1, is connected to the reverse voltage, the armature 32 is pulled upwards against the spring 35, whereby the distance between the current bridge 33 and the stationary contacts 30 is increased , 31 increases the more the higher the reverse voltage is. In general, it will be expedient not to let the armature 32 strike the pole shoes 50, 51 even at the highest blocking voltage, so that rebound and additional abrasion can be avoided with certainty. Rather, the armature floats back and forth in the rhythm of the reverse voltage, with a suitable choice of the spring characteristics and, if necessary, eddy current damping in the short-circuit winding 34, that an overshoot does not occur in the switch-on direction. However, the ends of the additional winding 53 can also be connected to one another via a valve 54 in such a way that the damping of this winding is only effective during the switch-on process. If the damping of the short-circuit winding 34 is sufficient, the additional winding 53 can also serve to premagnetize the switch-off magnet system, in particular when the spring 35 is set so that the current bridge 33 rests on the stationary contacts 30, 31 under its sole influence. If the switch-on time, as is the case with rectifiers with voltage regulation by shifting the ignition insert, is in the area of higher voltage, this can be taken into account in two ways. Either the contact spacing is selected somewhat larger in the idle state or the rectifier 19 (see FIG. 1) is bridged by a suitably selected resistor 21 such that the coil is so strongly excited before it is switched on that the current bridge is in each case on one sets a sufficiently large distance. Patent claims: 1. Arrangement for controlling electromagnetic alternating current synchronous switch, which at least an armature, an associated current bridge and an on and off magnet system for actuating the armature, the current bridge in its rest position in one the specified distance of less than 0.1 mm from the fixed contacts is kept, characterized in that at the latest at the onset of the reverse voltage by energizing the disconnection tmagnetsystems one on the armature in disconnection direction Acting force arises which causes the current bridge to exceed its rest position in the mentioned direction and its distance of the fixed contacts at least as much as the reverse voltage itself increases. 2. Arrangement according to claim 1, characterized in that the winding of the switch-off magnet system is due to the reverse voltage itself or to a voltage derived from it. 3. Arrangement according to claim 1, characterized by means which cause that in the disconnection direction effective force begins at a specified time before the current zero crossing. 4. Arrangement according to claim 3, characterized in that the winding of the switch-off magnet system is applied to a voltage that only becomes effective at an inductance when the main current decreases. 5. Arrangement according to claim 4, characterized in that the inductance is saturated The choke is, the voltage acting on the switch-off magnet system due to the switch-off magnetization is produced. 6. Arrangement according to claim 5, characterized in that the saturated throttle as Switching choke is formed and generates a low-current stage, during which the contact separation is brought about. 7. Arrangement according to claim 1, characterized by means for damping the movement of the Anchor. 8. Arrangement according to claim 7, characterized in that the damping is primarily caused by eddy currents in the armature. 9. Arrangement according to claim 7, characterized in that the damping by a Damping winding on the switch-off magnet system is effected only when decreasing Magnetic flux in the switch-off magnet system carries current.