DE1181775B - Device for switching off loads connected to alternating current, preferably at a higher frequency - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY GERMAN VfflWWl · PATENT OFFICE Internat. Class: H 02 c

EDITORIAL

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German class: 21c - 35/07

S 76657 VIIId / 21 c
November 11, 1961
November 19, 1964

As is well known, the switching of an alternating current preferably makes a higher frequency Consumers have particular difficulties because of the short periods of time before the voltage returns the switching paths cannot be sufficiently deionized to avoid reignition. These difficulties are exacerbated when the consumers lead reactive currents, the one Create a phase shift between current and voltage at the switching path. Particularly unfavorable are the conditions when the consumers are pure reactive resistances, such as capacitors, are.

To switch such consumers, it is known to use switching devices with main and pre-contacts, to divide the switching process into two stages. It is also known in the area of the switching path To attach blow coils through which the current to be switched flows and through the corresponding Magnetic field should extinguish the switching arc. The known devices do not work satisfactorily, In particular, difficulties arise when the frequencies of the to be switched Current much higher than the mains frequency, for example in the frequency range from 1000 to 10,000 Hz lie.

It is also known to connect two switching paths in series and design the second switching path as a high vacuum fuse. A series connection of two interruption points has also become known, in which the switching instant of an interruption point is influenced by the current intensity. Devices have finally been used in which one switch takes over the switch-on process and another switch takes over the switch-off process. Attempts have also been made to connect electrolytic lightning protection devices. Furthermore, circuits are known in which electrical arcs are to be extinguished by means of capacitor discharge or in which direct current arcs are eliminated by connecting capacitors in parallel. Finally, there are also arrangements for suppressing switching sparks by arranging two switching points with different switching times. Rectifiers connected in parallel have also been used to switch off inductances in DC circuits. Induction coils designed as transformers for push-button relays are also known in which the secondary winding is short-circuited via a capacitor. In a known technical solution, the contacts of the switching device to be actuated is used for switching medium frequency to switch off
Alternating current preferably higher frequency
connected consumers

Applicant:

Dr.-Ing. Gerhard Walter Seulen,

Remscheid, Ronsdorfer Str. 54

Named as inventor:

Dr.-Ing. Gerhard Walter Seulen, Remscheid

ters the series connection of a choke and an auxiliary switching path connected in parallel, the choke is provided with a bias winding which excites with direct current when it is switched off will.

It is also known to switch off capacitors in medium-frequency switchgear switching capacitor units a direct current magnetizable choke coil before switching off to be connected in parallel in order to reduce the current to be switched by the size of the vector value. With such a Arrangement is by means of the DC magnetization of the choke coil its inductance in each case adapted to the size of the capacitor unit to be switched. The latter solution has proven itself, however, it has a significant disadvantage that the DC magnetizable choke coil is very is expensive in terms of space requirements and manufacturing costs, since they are designed for the full continuous current got to. The auxiliary switching devices that are assigned to this choke coil must also be designed for continuous current his, which is both in terms of space requirements and in terms of weight and manufacturing costs has an unfavorable effect. Ensuring the necessary subsequent circuits on the individual devices also requires additional auxiliary relays or contactors, which also take up the space and the Increase costs. Finally, the DC control circuit requires a lot of technical effort because an adapted direct current value can be assigned to each capacitor stage of different sizes got to.

The invention avoids the disadvantages of known devices described above. She provides one Device for switching off an alternating current, preferably a higher frequency than the mains frequency Capacitors under load with the help

409 728/406

represents an inductance in which, according to the invention, the inductance in the form of a choke coil with a corresponding Reactance immediately after switching off the capacitor unit to be switched off is connected in parallel with this capacitor unit.

A b b. 1 shows the device according to the invention, designed for switching a capacitor. The feeding network, preferably of a higher frequency than the network frequency, is denoted by 11-12. It can

the switching bridge 46 moves in the direction of the arrow 45, whereby the inductance 49 of the capacitor 43 is switched off and immediately afterwards this capacitor via the switching paths 47 'and 47 " 5 'is connected to voltage. This design of the switching device is particularly advantageous because the switching bridge 46 is operated by a switch drive in such a way that the auxiliary switching path 50 ', 50 "briefly after opening the main switching path 47 ', 47 "closes

This involves a single-phase generator, a static and vice versa briefly before the main tables close Frequency multiplier, an inverter switching path 47 ', 47 "opens.

or a busbar connected to the current higher A b b. 5 shows a specific embodiment of a

Frequency is fed in, act. The capacitor jumper for the in connection with Fig. 4

13 is via the main switching path 14 with the current-described switch. In this case, inven-

source 11-12 connected. The main switching device 14 has two switching bridges, according to the invention, the electrical

two interruption points 14 'and 14 ", which are isolated from one another by means of trisch, but from the same

the switching bridge 14 '"are closed. To switch off the capacitor 13, the switching bridge 14 '' 'has been opened in the direction of arrow 15, whereby the contacts of the switching path Switching sparks or arcs are formed. Briefly after opening the switch 14, the auxiliary switch 17 is in Direction of arrow 18 closed. In the example shown, this auxiliary switch is also with two contact points 17 'and 17' "as well as the contact bridge 17". By switching on auxiliary switch 17 the inductor 16 is connected in parallel to the capacitor 13 to be switched off, whereby the current of the to interpret existing creepage distances at the open contact points 14 'and 14 ".

In many cases, the auxiliary switching path can be completely separated from the main switching path be housed in another area of the switching device.

According to a further development of the inventive concept

Drive can be operated off. 51 'and 51 "are the fixed contacts of the main switching path as well as 52 'and 52 "the fixed contacts of the auxiliary switching path. The switching bridge 56 for the The main switching path is from the switching bridge 57 for the auxiliary switching path through an insulating layer 53 isolated. When the switch is operated in the direction of arrow 55, the main switching path closes 51 after the auxiliary switching path 52 has opened. When the switch is operated in the direction of the arrow 54 closes the auxiliary switching path 52 after the switching path 51 is open.

Because of the extremely low temporal loading of the spark or arc on an erasable auxiliary switching path with rated current, this can be reduced with a residual value of klei. Immediately after Schliemann _n en contact pieces and a light switching bridge SEN of the switch 17 will go out of the switching spark or be executed. However, it is against full collective arcs at the switch 14, since at this point in time there is rail voltage with regard to the clearances and the contact spacing of the separating points of this switch
already relatively large and maintaining a 35
Discharge with the residual current value is not possible.
A b b. 2 shows the vector diagram. At 21 it is
Voltage on the feeding network 11-12 is shown. 22nd
is the current flowing through the capacitor at

closed switch 14. 23 is the current which, at 40 kens, the device should be designed so that Closing the switch 17 through the inductance 16, the inductance in such a way in the vicinity of the contact points flows. This current is made up of that of the main switching path or main switching paths Ohmic current component 24 and the inductive current is arranged that by means of magnetic blowing action component 25. The inductive current component 25 compensates for the switching sparks or arcs of the switching points the capacitive stream 22, so that the current at 45 of the main switching sections immediately after the switch-on Switching path 14 is blown from the value 22 to the value th of this inductance. 24 is reduced. At the same time, this current is in A b b. 6 shows such an embodiment. At

Phase brought to voltage 21 and immediately the current source 61-62, the capacitor 63 is over turned off. the main switching path 64 'and 64 "connected,

A b b. 3 shows a further embodiment of the invention when the switching bridge of the switching device in the direction proper device. The power source 31-32 of the arrow 65 is moved. When the switching power is moved Via the two switching paths 34 'and 34 "the bridge in the direction of arrow 68 opens the main capacitor 33. Immediately after this switching path 64 'and 64 "opens and then closes Switching paths, the switching path 37 is closed, the auxiliary switching path 67 'and 67 " whereby the one tailored to the size of the capacitor 33 is that tailored to the size of the capacitor 63 Tuned inductance 36 connected in parallel with this inductance 70. At the main switch will be. distance, the current is reduced to the residual value.

A b b. 4 shows an embodiment of the invention, the switching spark or arc is the bubble the disconnection of the capacitor 43 from the effect of the instant of switch-on with full rated network 41-42 by a single pole switch 44, the 60 exposed inductance 70. the Equipped with rear contacts 50 'and 50 "ampere turns of this inductance have one is accomplished. The switching bridge 46 moves extremely high instantaneous value, which also leads to uncertainty in the direction of arrow 48, whereby the switching most favorable cases, d. H. for example at very high stretch 47 'and 47 "are opened. Immediately frequencies of 10,000 Hz and above, the Schaltnach Opening this switching path closes the 65 sparks and is instantly extinguished. Compared to Bridge 46 the switching paths 50 'and 50 ", whereby the known magnetic blowing devices the inductance 49 parallel to the capacitor 43 switching devices, the advantage is achieved here that the blower switches will. When the capacitor is switched on, the size of the main current has a practical effect

is independent. The practical application shows that, for example, when switching off a capacitor of 100 kVA on a 100 volt 2000 Hz network, the number of ampere turns of the inductance 70 17 500 for is the instant when the inductance is switched on.

The invention is not restricted to the examples shown in the figures. In particular is it is possible to combine the various forms of solution according to the invention.

In some cases it has proven to be useful to use the inductors with iron or ground cores equip to influence the inductive resistance. By appropriate shaping these cores can also influence the blowing effect in terms of their strength and direction, whereby the contact erosion on the main switching path can be reduced.

Claims (7)

Patent claims: 1. Device for switching off an alternating current preferably higher than frequency Mains frequency connected capacitors under load with the help of an inductance, thereby characterized in that the inductance is in the form of a choke coil with a corresponding Reactance immediately after switching off the capacitor unit to be switched off is connected in parallel to this capacitor unit. 2. Apparatus according to claim 1, characterized in that the main switching path for the Capacitor with the auxiliary switching path for the choke coil are combined in one switching device and operated via a common switching drive. 3. Device according to claim 2, characterized in that that the main and auxiliary switching sections are each provided with two interruption points that are alternately closed or opened by the same switching bridge. 4. Apparatus according to claim 2, characterized in that for the main switching path and the auxiliary switching path is each provided with a switching bridge, the two switching bridges from each other are isolated and operated by the same drive. 5. Apparatus according to claim 1 or the following, characterized in that the choke coil is arranged in the vicinity of the contact points of the main switching path or paths to by means of a magnetic blowing effect, switching sparks or arcs at the contact points of the To delete the main switching path or paths immediately upon switching. 6. Apparatus according to claim 3, characterized in that the choke coil consists of a series or parallel connection of several inductors, each of which is assigned due to each individual contact point of the main switching paths τχιτ blowing. 7. A circuit for operating the device according to claim 1, characterized in that for Switching off the choke coil of the capacitor unit is switched in parallel while switching on the parallel connection is canceled, with the shutdown command of the Main switch and the connection command of the auxiliary switch be given in such a way that the auxiliary switch is practically in the opening time of the Main switch closes. Considered publications:
German patent specifications No. 320 803, 529 863,
971, 554 313, 610 831, 612 272, 615 623,
712 498,905 038. 1 sheet of drawings 409 728/406 11.64 ® Bundesdruckerei Berlin