DE19649979C1 - High-voltage switchgear electrodynamic drive system - Google Patents

Abstract

An electrodynamic drive including an armature (4) actuated by means of two coils (2,3) supplied alternately from a voltage source (1), the armature (4) in turn actuating a contact of a switching device In the course of a switching event through the armature a first auxiliary contact arrangement (6,7,9,10) on one side separates its driving coil (3,2) from the voltage source (1) and on the other side, a second auxiliary contact arrangement (6,7,9,10) is actuated and prepares a coil (2,3) for activating a subsequent switching event. The auxiliary contact arrangement actuated by the armature (4) comprises sliding contacts (6,7,9,10) which are closed by the armature and with it form a current path.

Description

The invention relates to an electrodynamic drive, ins especially for high-voltage switchgear, one by two Actuating alternately feedable coil from a voltage source Tigbaren anchor, which has a switch to be driven contact of a switching device actuated.

Such an electrodynamic drive for electrical Switchgear goes with regard to the actuation of the Benden switching contact of the electrical switching device alternately feed one of two from a voltage source baren coils actuated armature, for example from DE 43 04 921 C1. With this electrodynamic drive it is guaranteed that a by the electrical Switch operation to be performed safely, but it does is not guaranteed that the electrodynamic drive immediately after a switching process has elapsed is ready for the subsequent switching process.

As a disadvantage comes with the known electrodynamic also drove that starting from that increasingly as Voltage source a capacitor bank is used, such as the drive device for one DC switch according to DE 38 41 592 A1 provides that Operability of electrical switching devices and thus is also restricted by high-voltage switchgear. The is particularly the case because the current flow un not interrupted indirectly after completion of a switching operation Chen, what with an unnecessary discharge of the condensate ren is connected.

The invention is therefore based on the object of an elek trodynamic drive according to the preamble of the An Proverb 1 to create, not only after the expiration of a Switching process without time delay immediately for the successor switching operation is ready, but by the also at the latest after completion of a switching operation of the egg gene current flow is to be interrupted.

According to the invention this is achieved in that Anchor in the course of a switching process on the one hand a first Auxiliary contact arrangement which drives the coil of separates the voltage source and on the other hand a second Auxiliary contact arrangement is operable, which for a subsequent switching operation to be activated coil ready.

The auxiliary cones can be actuated by the anchor Clock arrangements advantageous from two on the inner order catch the coils arranged, closable by the anchor and with this sliding contacts forming a current path. This should advantageously have a length that the axial Corresponds to the length of the anchor as well as an entry surface for one trouble-free entry of the armature into the coils. Deviating of this height the sliding contacts can of course a lower height can also be selected, but then the sliding contacts arranged on the inner circumference of the coils must be arranged on the inlet side for the anchor. The height the sliding contacts will eventually be replaced by a safe guiding of the armature within the coils.

An activation of the respective, after a movement of the An kers from one to the other reel for one to follow the switching process made ready for the coil electrodynamic drive according to the invention in dependence on the arrangement of the coils and the sliding contacts of the first  and second auxiliary contact arrangement take place when the corresponding sliding contact is closed by the armature.

According to a preferred embodiment of the electro dynamic drive the connection of the first sliding contact tes of the first auxiliary contact arrangement with the voltage source via a switch assigned to the switch-off process and corresponding to the connection of the switch on process arranged coil over a assigned to the switch-on Counter.

Slides in the electrodynami designed according to the invention drive, in which the on and off process orderly switch can be controlled externally, the armature off one of the two coils, the current flow through the the coil is interrupted and the drive process ends. At the same time, the sliding contacts become the auxiliary contact arrangement the other coil is contacted by the armature, so that the drive is ready for reverse switching is made. But that means that the voltage source only releases energy for the respective switching process, so that at Use of capacitor banks as a voltage source Operational readiness for a relatively large number of and switch-off operations is guaranteed. It is suitable the electrodynamic drive designed according to the invention not only for circuit breakers, but also the ones through it The effects are also seen when it is used for load, disconnector and earthing switches for high and low Medium voltage reached.

The invention is based on two exemplary embodiments hand explained in more detail a schematic drawing.

The associated drawing shows in  

Fig. 1 is an electro-dynamic drive, partly in section, which is ready for a switch-off operation,

Fig. 2 shows the electrodynamic drive according to Fig. 1 partially in section, which is ready for a switch-on and

Fig. 3 a compared to Fig. 1 and 2 modified electro dynamic drive partially in section.

As shown in FIGS. 1 and 2 show, the electrodynamic drive consists of two alternately from a voltage source 1 ge fed coils 2, 3, whereby as a voltage source 1, a Kon densatorbatterie for use comes as well as out of the armature 4, through the coils 2, 3 can be actuated and connected via the switching rod 5 to the switching contact (not shown) of a high-voltage switching device. The coil 2 is assigned to the switch-on process in the direction of arrow 18 and the coil 3 to the switch-off process in the direction of arrow 19 . On the inner circumference of the coil 2 there is a first contact arrangement consisting of two sliding contacts 6 , 7 and on the inner circumference of the coil 3 there is a second contact arrangement also consisting of two sliding contacts 9 , 10 auxiliary contact. While the second sliding contact 10 of the second auxiliary contact arrangement and the input 12 of the coil 3 are directly connected to the voltage source 1 , the first sliding contact 6 of the first auxiliary contact arrangement is connected to a switch 13 associated with the switch-off process and the output 14 of the coil 2 is connected to the switch-on process assigned switch 15 in connection with the voltage source 1 , both switches 13 , 15 being externally controllable.

From Figs. 1 and 2 can also be seen that the first sliding contact 9 of the second auxiliary contact arrangement with which a gear 16 of the coil 2 and the output 17 of the coil 3 with the second sliding contact 7 of the first auxiliary contact arrangement is connected, and that the armature 4 depending on whether it is located in the coil 2 assigned to the switch-on process or in the coil 3 assigned to the switch-off process, together with the sliding contacts 6 , 7 of the first auxiliary contact arrangement or the sliding contacts 9 , 10 of the second auxiliary contact arrangement in each case a closed Current path forms.

If the high-voltage switching device is to be switched off, the output 17 of the coil 3 is connected to the voltage source 1 by actuating the switch 13 via the current path formed by the sliding contacts 6 , 7 and the armature 4 . This leads to a movement of the core 4 in the direction of arrow 19 . If the armature 4 slides out of the coil 2 assigned to the switch-on process, the circuit closed up to that point via the sliding contacts 6 , 7 and the armature is opened and thus also the coil 3 is separated from the voltage source 1 , so that when a capacitor bank is used no further discharge takes place as voltage source 1 . Since this process is connected to a safe reception of the armature 4 by the coil 3 , the armature 4 now forms, as shown in Fig. 2, together with the sliding contacts 9 , 10, a current path, so that the electrodynamic drive for the subsequent switching process of the high-voltage switching device is ready. The switch-on process is carried out when the switch 15 is actuated and thus the output 14 of the coil 2 is connected to the voltage source 1 .

Referring to FIGS. 1 and 2 corresponds to the height of the Gleitkon contacts 6, 7 and 9, 10, although the length of the armature 4, but the intended by the invention, effects can be achieved even when the acceleration of the armature 4 at its cross slide in the other coil 2 , 3 is so large that a safe termination of the switching process is guaranteed by its kinetic energy and thus by designing the sliding contacts 6 , 7 and 9 , 10 , in particular bezüg Lich a shorter length, an early interruption of the circuit closed by the sliding contacts 6 , 7 or 9 , 10 and the armature 4 , that is to say before the armature 4 leaves the respective coil 2 or 3 .

The electrodynamic drive according to FIG. 3 corresponds essentially to that according to FIGS. 1 and 2, but in contrast to the electrodynamic drive according to FIGS. 1 and 2, the coils 2 , 3 and the sliding contacts 6 , 7 are changed here by a changed circuit arrangement and 9 , 10 of the first and second auxiliary contact arrangement in cooperation with the switches 13 , 15 associated with the switch-on and switch-off process and the voltage source 1 in the form of a capacitor bank, the discharge of the capacitor bank during a switching process is reduced to a minimum and at the same time the electrodynamic drive for one subsequent switching operation made ready. In this electrodynamic drive, the second sliding contact 7 of the first auxiliary contact arrangement and the output 14 of the coil 2 are directly connected to the voltage source 1 , while the first sliding contact 9 of the second auxiliary contact arrangement is connected via the switch 15 assigned to the switch-on process and the input 12 of the coil 3 can be connected to the voltage source 1 via the switch 13 associated with the switch-off process. According to this circuit, the first sliding contact 6 of the first auxiliary contact arrangement is finally connected to the output 17 of the coil 3 and the second auxiliary contact 10 of the second auxiliary contact arrangement is connected to the input 16 of the coil 2 .

From this figure it can also be seen that the sliding contacts 6 , 7 and 9 , 10 have a smaller height than those according to FIGS. 1 and 2, but with the end face of the one running side for the armature 4 of each of the two coils 2 , 3rd from close so that the respective circuit is interrupted by the armature 4 when it has left the sliding contacts 6 , 7 and 9 , 10 . This also happens here when leaving coil 2 or 3 . It is also possible for the sliding contacts 6 , 7 and 9 , 10 to end before the end of the inlet side for the armature 4 of each of the two coils 2 , 3 , as is also a variant for the sliding contacts 6 , 7 and 9 , 10 of the electrodynamic drive according to FIGS. 1 and 2 provides.

Claims (9)

1. Electrodynamic drive, in particular for high-voltage switchgear, which has an armature ( 4 ) which can be actuated by two coils ( 2 , 3 ) which can be alternately fed by a voltage source ( 1 ) and which actuates a switch contact to be driven by a switching device, characterized in that the armature ( 4 ) in the course of a switching process on the one hand a first auxiliary contact arrangement ( 6 , 7 , 9 , 10 ) which separates the coil ( 3 , 2 ) driving it from the voltage source ( 1 ) and on the other hand a second auxiliary contact arrangement ( 6 , 7 , 9 , 10 ) can be actuated, which makes the coil ( 2 , 3 ) to be activated for a subsequent switching operation ready for operation. 2. Electrodynamic drive according to claim 1, characterized in that the auxiliary contact arrangements which can be actuated by the armature ( 4 ) each have two on the inner circumference of the coils ( 2 , 3 ), are closable by the armature ( 4 ) and form a current path with this Sliding contacts ( 6 , 7 , 9 , 10 ) exist. 3. Electrodynamic drive according to claim 1 and 2, characterized in that the arranged on the inner circumference of the coils ( 2 , 3 ) sliding contacts ( 6 , 7 , 9 , 10 ) have a length which is in Chen wesentli the axial length of the armature ( 4 ) corresponds. 4. Electrodynamic drive according to claim 1 to 3, characterized in that after completion of the movement of the armature carried out during a switching process from one coil to the other ( 2 , 3 ) ready for a subsequent switching process coil ( 3 or 2 ) can be activated is when the corresponding sliding contact ( 6 , 7 , 9 , 10 ) is closed by the armature ( 4 ). 5. Electrodynamic drive according to claim 1 to 4, characterized in that the connection of the first sliding contact ( 6 ) of the first auxiliary contact arrangement ( 6 , 7 ) and the coil ( 2 ) with the voltage source ( 1 ) via one of the switch-off and one assigned the switch ( 13 , 15 ) assigned to the switch-on process. 6. Electrodynamic drive according to claim 1 to 5, characterized in that the second sliding contact ( 7 ) of the first auxiliary contact arrangement ( 6 , 7 ), the first sliding contact ( 6 ) via the switching operation associated with the switch ( 13 ) with the voltage source ( 1 ) can be connected, with which the switch-off operation is assigned, to the voltage source ( 1 ) connected coil ( 3 ), while the first sliding contact ( 9 ) of the second auxiliary contact arrangement ( 9 , 10 ), the second sliding contact ( 10 ) the voltage source ( 1 ) is connected, with the switch-on associated with the voltage source ( 1 ) via the switch-on associated switch ( 15 ) connectable coil ( 2 ) is connected. 7. Electrodynamic drive according to claim 1 to 4, characterized in that the connection of the first sliding contact ( 9 ) of the second auxiliary contact arrangement ( 11 ) and the coil ( 3 ) with the voltage source ( 1 ) via one of the switch-on process and one of the switch-off process assigned switch ( 13 , 15 ). 8. Electrodynamic drive according to claim 1 to 4 and 7, characterized in that the first sliding contact ( 6 ) of the first auxiliary contact arrangement ( 6 , 7 ), the second sliding contact ( 7 ) is connected to the voltage source ( 1 ) with which Switch-off process, connected to the voltage source ( 1 ) via the switch ( 13 ) associated with the switch-off process coil ( 3 ) is connected, while the second sliding contact ( 10 ) of the second auxiliary contact arrangement ( 9 , 10 ), the first sliding contact ( 9 ) is via the associated switching on the switch (15) connectable to the voltage source (1), with the switching on of the assigned, is at the voltage source (1) connected to the coil (2) in combination. 9. Electrodynamic drive according to claim 1 to 8, characterized in that the switch on and off associated switch ( 13 , 15 ) are externally controllable.