DE382284C - Device for converting three-phase currents into rectified high-voltage currents, especially for the operation of X-ray tubes - Google Patents

Description

GERMAN EMPIRE

ISSUED
ON OCTOBER 1, 1923

REICH PATENT OFFICE

PATENT LETTERING

CLASS 21 g GROUP 18

(C 29343 VIIIJ2ig ⁱ )

Orso Mario Corbino and Dr. Giulio Cesare Trabacchi in Rome.

Device for converting three-phase currents into rectified high-voltage currents, especially for the operation of X-ray tubes.

Patented in the German Empire on July 9, 1920.

According to the Union Treaty of June 2, 1911, the priority for this application is örund
of the applications in Italy of July 29, 1917, February 26, 191a and April 25, 1918.

We already know devices in order to deal with other hard tubes with independent flow from the three-phase current of an urbanization, but let us see one-sided periodic distribution network with a single one; soft tube the supply line of currents interrupted currents of the primary side of a highest intensity not to the ones with very transformer supply. Wireless parts operating at high frequencies are then obtained in a sequence that is required by induction graphics. This results from the discharges below, which have a limit which can be avoided with the interruption, which has the ability of a transformer to operate synchronously, especially if the consumer, e.g. As an X-ray tube, they WEI öfftergibt for those with a selector (selector), and only the opening or UN '' is voltage currents provided when the aufeinterbrecherströme. other currents in the primary winding

These devices work very well when the coil core is magnetically

around the power supply of one or more, sieren.

The invention now aims to make the device so that using periodically interrupted three-phase currents each interruption of the current after a suitable interval a current short-circuit follows, through which the coil core is magnetized in the opposite sense as before, i.e. H. magnetized will. The two impulses in the same direction from the power interruption and the ίο following power connection, which is a high voltage the secondary circuit can correspond, are fed to the consumer through a switch of a special type, the High voltage works synchronously and the connections between the secondary and reverses the transducer as soon as the high voltage of the secondary side is reversed as well will.

The apparatus with which these results are to be achieved are of three different types Embodiments built that fit for different cases, depending on the feed network is laid with or without a neutral conductor and there are high-frequency discharges or currents desires to achieve almost a direct current, or else it is appropriate to the induced Discharges at intervals of lower frequency to follow. Receives in all cases one has the possibility of generating very strong currents, as one would for the radio. graphics of high intensity or extreme performance or for extremely high tension Currents as they occur in the hard tubes for deep radiography. In the figures are various examples Embodiments of the invention shown schematically.

Fig. Ι relates to a distribution network with a neutral conductor and also to the application an artificial zero point.

Fig. 2 shows a rotating switch for the secondary currents for the facility according to Fig.i.

Fig. 3 illustrates the installation of the apparatus in a distribution network without a neutral conductor or artificial zero point.

Fig. 4 illustrates a modification of the Fig. 3 illustrates feeding a _r Various NEN number of secondary electric pulses for each revolution of Quecksilbertinterbrechers is made possible with the directional switching using breaker.

Fig. 5 shows an arrangement in which

current pulses of lower frequency are obtained at lower rotational speed.

Finally, figs. 6 to 8 show modified

embodiments of the invention.

Case A.

In a feeder network with neutral or artificial zero point one ι apparatus schematically illustrated uses as in Fig.. A transformer with a very high gear ratio has six primary circuits 1-1, 2-2, 3-3, 4-4, 5-5, 6-6 on the iron core, all of which are wound in the same direction.

A rotating mercury beam underlayer / in an inert gas with six lamellae a, b, c, d, e, f isolated from each other and from the stand has a single mercury beam that hits the six lamellae one after the other and thus individually with the one connected to it Conductor connects. The turbine axis is driven by a synchronous motor, which makes one revolution for two periods of the feeding current.

A selector or selector reverses the connections between the tube and the secondary windings at every third of the period and is driven by the same motor that keeps the mercury turbine in rotation.

The six primary windings of the transformer are connected in series in pairs; the phases α, β, γ are connected to the connection points. The six free ends are connected to the lamellae in such a way that the lamellae a, c, e lie on three primary turns which cause magnetization in one direction when a direct current from the supply lines flows through. The lamellae b, d, f are connected to the three other primary circuits, which cause the reverse magnetization when the same current flows through them. The housing of the interrupter, and consequently the mercury beam, is connected to the zero point N.

As soon as the mercury beam, which makes a revolution every two periods , hits lamella a, which is then connected to it, a current is generated whose intensity at the moment the mercury hits the lamella not only depends on the state of the circuit, but also depends on the phase in which the voltage of the wire α of the network is. This phase can be selected at will by rotating the stator of the motor driving the interrupter.

When the current is interrupted, in the secondary circuit, not shown in Fig. 1 a very high voltage induced, which in the consumer circuit z. B. in an X-ray tube can generate a current that lasts for a considerable period of time, depending on the Conditions of the consumer.

The Ouecksill beam leaving the lamella α hits the lamella b after a suitable pause and at an interval of a third of the period of the current connection with α , thereby activating the primary circuit 2-2, which in connection with the phase brought to the same value as before α at this moment β of

the same current flows through as ii. Only in 2-2 the current flows, as previously described, in the opposite direction as in ii, thus magnetizing the coil core.
This current connection thus generates a secondary voltage in the same sense as that caused by the interruption of the primary circuit ii. Since this new voltage occurs before the voltage resulting from the previous power interruption has dropped to a value below the circuit voltage, there is a new increase in the voltage and the current of the secondary side with all the advantages already mentioned therein.

As can be easily seen when following the mercury circulation from Fig. 1, one has during an orbital movement six such impulses, which in intervals of one third of the period and line up with successive reversals of the secondary side of the coil. It must therefore be between the coil and the consumer apparatus are switched to a changeover switch that controls the circuit reversed at every third of the period. The device in Fig. 2 serves this purpose.

A cage made up of three columns placed at the corners of an equilateral triangle is placed on the synchronous motor in such a way that the motor axis penetrates the base triangle in the center. An axis A made of insulating material is rigidly connected to the motor axis, the upper end of which runs in a bearing arranged in the center of the upper triangular cage.

As can be seen in Fig. 2, four arched pieces j, / ', h, the radius of which corresponds to the distance from the axis A , sit on the pillars I ₃ Γ made of insulating material. The insulating axis A carries a metal ring k at the level of these curved pieces, which is provided with three radial arms made of aluminum offset from one another by I2o °.

The upper bars m ₃ n, p lie parallel over the lower bars m, ri, f '. There are 'Isolierarme i ending in a short aluminum head between the aluminum rods. These heads a, b, c, d ', V, c' at the ends of the insulating arms are conductively connected by vertical rods x, y, ζ.

If one follows the circulation of this apparatus, it follows that if the small arches /, h and / ', h' are horizontally connected in one position, i.e. TJ with R and TJ ' with K ₁ after a sixth of a turn (corresponding to a third of a period ) a connection is established in the vertical direction, i.e. U'an K and TJ 'will lie on R.

The secondary winding is connected to the one upper bow piece through R and to an un-

fV tere arc connected by K , while the consumption apparatus is connected to TJ and TJ '. As a result, the connections are reversed every third of the period. The arc length is dimensioned so that the connection remains set, is \ such as voltage used, that is, during the interruption, the j between pause and a small portion of the following power circuit, and in that the connection is established when the secondary voltage is very herabgegangeh. The voter or selector is keyed on the axis in such a way that a power connection is always established at the moment of an interruption.

Since the motor used to drive the selector axis and / 5 of the interrupter has four poles, it could assume four different synchronous positions. The order i8o ° of the neutral conductor are opposite to the current direction along equivalent to 90 to ⁰ cause a reversal of the direction of this current and then the current that flows through the consumption apparatus. The position taken by the engine is indicated by the usual synchromesh indicators.

By omitting the connections of three primary windings with three alternating selected slats, d. H. the even or the odd depending on the position at the beginning was chosen for the selector, the interrupt pulses decrease for each on three.

With such primary connections one could only use the upper part of the selector, by leading one pole of the coil directly to the tube, while the other pole is attached to one of the small upper bow-pieces, the other of which is in communication with the tube stands. Because the three serviceable interruptions at intervals of thirds of the period and occur exactly at every third period, there are connections between the upper ones Elbow pieces, and the tube is traversed by all impulses in a single direction, which corresponds to these interruptions, and only from these pulses.

By arranging three separate breakers on the three phases or the three The wires leading to the lamellas used can have the three impulses on two and even on one for each revolution to be reduced.

This device is suitable for all hard and very hard tubes in radioscopy and radiotherapy, and is apparently very suitable for regulating the intensity in such tubes, there it gives the possibility to change the number of pulses (for a frequency of 50 periods) from 50 to modify up to 150.

In the absence of a neutral, and if it is not appropriate, an artificial -zero-

To establish a point, the apparatus remains in its essential parts as just described, only that instead of a single beam in the interrupter two are provided, which, as in AbI). 3 given at g ^l , g ² , are offset from one another by 60 ^c. Nothing changes in the connections between the primary windings, lamellas and the network, except that, since there is no zero point, the massive parts of the breaker and the small beaks of the jet apparatus are isolated, as in all ordinary apparatus of this type.

If one follows the pair of beams as they circulate, it can be seen that they close and interrupt the current one after the other between two phases following at intervals of an eighth of a period by directing these currents, which flow in a single direction in the rotating beam, into the primary windings, which are wound in series in such a way that a magnetization of the core in one sense is followed by a reversal in the next current circuit.
This results in a mode of operation that corresponds to that of the apparatus described above, ie there are six pulses for each cycle, which are reversed in every third period and directed in the same direction from the selector described above into the consumer apparatus.

In order to enable the following j current interruptions to be made usable in this device at intervals of ² / _g periods (three in each cycle), in such a way that the! Selector as in case A, very hard tubes: when feeding, one, two or three discharges can be fed into a tube with each cycle. Two three-pole breakers are used for this as shown in Fig. 4.

The three feed lines α, β, γ are placed at the base of three blades of an ordinary three-pole changeover switch, so that the lines can either be connected to contacts 1-4, 5-2, 3-6 of the primary windings in the manner described above or only can connect to the outer ends 4, 2, 6 of the primary side of the same name.

A second three-pole switch off and with three single diameters is such einge- \ switches that its diameter associated with the outer ends of the primary windings 6,4, 2 in conjunction. If you put these three knives down and the knives of the first switch up, the result is the same circuit as described last, ie the ends 6, 4, 2 are on the lamellas f, b, d and the phases at contacts 1-4, 5-2, 3-6. If the knife position is reversed, as can easily be seen, there is a circular reversal in the contact of the primary windings with the laminations connected to them, and the phases are then connected to the primary ends 4, 2, 6. With the connections arranged according to Fig. 4 the case will occur that, when the two mercury jets are in the position in which the contact between the lamellae α and b is interrupted, a current is interrupted in the primary side 1-4, which flows through this primary winding, graining from α , from right to left. When the mercury rays come into contact with or between b and c , no current connection is established and interrupted, because the lamellae h and c are on the same phase. During further run up to the connection cd stream is introduced and suspended in the same sense as flows through the primary side in series 3-6 in the previous case, as it is β removed between y and whose potential difference in the elapsed _^2/3 periods equal to has become between α and γ .

If the mercury rays continue to circulate, it results that no current will flow between d and e and / and α, while after the pulses already considered between α and b and c and d another identical pulse will repeat between e and f , so that three separated by intervals of _^2/3 periods pulses reached, come.

Since the three switch blades of the second switch are independent of each other, see above one can evidently reduce the impulses to two or even one with each revolution; man only needs to leave one or two knives in the neutral position for this purpose.

Case C.

If one secondary Stark currents of high voltage pulses with lower frequency and with a lower angular velocity ah having peripheral organs will receive, use is made of the device according to FIG. 5.

From the three network conductors α, β, y one takes 10c transformer by means of known devices, z. B. with the Scott system shown in Fig. 5, two two-phase voltages in separate windings. If you combine their centers by a neutral conductor N, four alternating voltages are available in the no wires A, B, C, D opposite N , which are lined up in the order of the letters at intervals of quarter periods.

The line N goes through the primary winding P of the coil to the single circulating mercury beam g of the usual breaker /. This has four mutually insulated lamellae α, b, c, d , which are connected to the wires A, B, ₁ C, D. The drive motor of the breaker is three-pole and makes one revolution every three periods.

Consequently, the mercury beam includes the lamellae at intervals from _^3/4 periods of the neutral N.

In the position of Fig. 5, the beam g applies the phased to N. This is followed by an interruption. In the case of the following current short-circuit on b, B, which occurs after a% period from the previous current short-circuit, the voltage in B will be the same as in A , but with the opposite sign. After the new interruption, lamella c and phase C come into operation at an interval of ^e / ₄ periods since A _{1 came} into effect and conduct a current into the primary winding that is the opposite of that coming from B. After the interruption in c, there is a new current reversal in phase D, and the same processes are repeated in the specified order. With each cycle there are four interruptions, which are followed by four opposite current circuits.

The empty space between the slats and the gear ratio of the Transformers are chosen so that the new circuit has the effect of the previous one Interruption cannot weaken, all with the definition of secondary voltages of the same mind. So you have, if z. B. the current has 65 periods and the motor as a result Makes 15 revolutions per minute, and 60 interruptions per second 60 power connections. These follow one another in such a way that the discharges are interrupted and the following current closure are of the same meaning while the direction of discharge from the subsequent interruption and closure is reversed. In other words: the polarity of the secondary winding of the transformer is reversed with every interruption.

You have to reverse the connections between the secondary side of the coil and the current sensor during the interruption phase and a little before the current is closed. This is achieved by one of the usual high-voltage switches, which are driven with the mercury beam by the same motor and reverse the connections with every quarter turn. For high useful voltages, the use of the usual opening discharges is recommended; and the operation of the switch f as in a \ simple selector or selector for ÖfEnungs- discharge.

The principle on which the present invention is based can be generalized by one derives from it other facilities that are even cheaper.

In the usual tub of the circulating breaker there is a periodic contact between a certain number of lamellae

len, which are regularly distributed over the circumference of the housing or the tub, and the mercury mass feeding the beam, d. H. the mass of the housing. Do you want all phases use, the number η of the lamellae must be a multiple of the number α of the phases.

The beam leads the touched lamellas the voltage-zUj whereby it transfers the current from the interrupter pan through a single primary winding, paves a way to the neutral conductor.

When the slats one after the other - Pe-

riode are touched, they are all in the same moment of contact Phase. The primary circuit is also made up of sequential moment currents in the same direction flowed through. When from contact with one lamella to contact with the following f- - period disappears, the tension becomes Equivalent from lamella to lamella at the moment of contact, but from the opposite one Be a sign. As a result, separate and successively reversed current pulses enter the primary circuit, with the magnetization is reversed after each interruption.

Assuming that the mercury beam makes one revolution every m-periods, will

the distance from one contact to the next

- be period,
n.

. It must therefore be:;

because n:
be:

= ko, where k is an integer, must

m a.

If one sets k = ι or η = α and a - 4, one obtains m = 3.

This is the case C above Solution.

If one wants to use the three-phase voltage directly, in which case α = 3, one must to have:

Jl

Since m must be whole, the insertion of is sufficient in this respect

k = 2 and m = 5, with η = k and α = 6.

This solution, which will be called Case D, requires a six-lamellar pan So connected in sequence with the three phases 1,2,3 are that the opposite lamellae are on the same phase. Necessary

is here a "circulating simple or diametrical mercury beam and a primary circuit with one connected between the masses of the interrupter trough and the neutral conductor single winding.

If the neutral conductor were not available and you did not want to create an artificial zero point, the help of another device would be sufficient, which is called Case E-ίο. According to this, the primary circuit has three windings, one end of which lies on the phases and the other end on the opposite groups of lamellas. Two rays g, g forming a 60 ° angle periodically connect two successive lamellae ι , with the two windings between phases 1-2, 2-3, 3-1 at intervals of ½ "/,., Period close and interrupt.

ao In 1 eicicn cases 1 the motor must run every five periods make a turn.

The switchover to the secondary side in the connections between the coil and the appliance must take place as soon as the jet hits the lamella, ie every ^{1 to} ₆ revolutions. You can therefore use the high-voltage switch already mentioned, which has the task of ^{reversing these connections on every 1} Z ₀ tour.

In the arrangements described above, the magnetization reversal of the core is after each interruption is achieved by reversing the current in the primary winding. but with two windings through which current pulses flow in opposite directions, the same purpose can be achieved, especially since the current flowing to zero is always one has only one direction. In this case you can have a breaker with diametrically opposite one another Use double rays that connect two opposing lamellas. One half of the slats is one after the other to the phases and the other half alternately to one and the other other free end of both windings laid. The tension on the slats must be in this The case repeats identically when the contact closes from lamella to lamella. So it must (with the symbols used above) be:

m ι

Since ■ - must include all phases and, on the other hand, the two primary windings must alternate regularly, - must be straight and an exact multiple of the phases, ie:

- = k «. = even number.

If α == 3, then k must be at least 2 and η = 12 and consequently m = 4.

This solution is equivalent to case A and only differs in that it has twice the number of lamellas and halving the number of revolutions of the interrupter. You only need two primary windings.

If α —4, one must have: η = 8, m = 2.

If α = 2, then η = 4, m = 2. That is the case with a single-phase current with zero point, represented by the center point an autotransformer (voltage booster).

The principle on which the invention is based can also be used for other devices pHette 1, inde.n one is the number of turns on the primary side reduced to one or three. This results in a significant simplification in the structure of the control panel.

i. The establishment according to FaIlA, the one Assuming neutral, allows a great simplification of the switchboard because of the Rheostat, the time interrupter (timer), etc. can be connected to a single wire that goes from the vessel to the zero point. But the switching sequence is even more complicated once it is a question of receiving discharges in a sense that is derived from the two Results in synchronous positions between them; these positions are orthozonal, which of the Engine can occupy. In addition, since the primary circuit has six windings, they are made not easy; likewise the connections are far from simplicity.

On the other hand, the use of an artificial neutral conductor (autotransformer in star connection) In practice it has proven itself so well that it is particularly advisable in all cases because if you build it appropriately in the manner described below, you get the windings the primary side can reduce to one. This makes the construction much easier and simplifies circuitry and maintenance without the practical advantages resulting from case A being lost and convenient use for all radiology requirements (heavy-duty radiography, Deep radiotherapy, radioscopy with rare or frequent radio) is canceled.

In order to achieve these results, the artificial zero point is constructed with a special type of autotransformer (Fig. 6), consisting of a system of three iron bars that are magnetically connected, as in ordinary transformers, and distributed over the three windings calculated for twice the mains voltage . The three centers of the three windings are united and form the zero point of the system. The free ends A ₁ B ₁ C are at the Pha-

Claims (10)

882284 sen α, β, γ; As can be easily seen, voltages of the same type, but opposite to A ₁ B ₁ C , appear at the other ends A ', B', C at every moment. The neutral conductor N is connected to a radial beam g through a single primary winding P , as in the case of the interrupter according to FaIlA. The lamellas a, a ', b, V, C ₁ c are connected to the ends of the windings A ₁ A', B ₁ B ', C ₁ C ίο connected. If the motor actuating the interrupter makes one revolution every two periods (as in case A), each interruption is followed by a current shorting of the zero point through the primary winding to an opposite voltage, and the same phenomena are obtained as in case A. If the contacts between A are left ', B', C and the corresponding lamellae and at the same time make the suitable connections already described on the selector. B. can be used for therapeutic purposes. If one or two contacts between A ₁ B ₁ C and the corresponding lamellae are omitted, the number of discharges for each revolution can be reduced. 2. As case D a device has already been described to reduce the speed of the circulating Parts to diminish. An analogous result can be achieved according to Fig. 7 if one only needs currents of great intensity. Here are connected to three phases with three suitably ⁰ to 120 displaced lamella length. The neutral conductor N goes to the jet arms g ', g ", which are diametrically opposed in such a way that when one arm leaves a lamella, e.g. The primary winding P is connected between the vessel and the neutral conductor N. In this case, too, the motor makes one revolution every five periods, and it does so again; get the phenomena described above; equivalent facility. ; 3. In order to achieve the same thing as in the previous case: but without using or constructing a neutral conductor, one can choose the arrangement according to Fig. 8, which however requires a primary side with three windings. ; The ordinary mercury beam interrupter has a six-blade, l ·, c, d, e, f and diametrically opposite beam arms g ', g ", the countertransference ■ lamellae successively connect. _ The three lamellas a, C ₁ e are on the three identical windings P ¹ , P ² , P ³ on the phases cc, ß, y, which in the sense of rotation of the interrupter ^! is still directly connected to the lamellae l ·, d, f in 1. If one follows the orbit of the jet, one obtains ^; that the interruption z. B. at α between the phases y, α after the pause and exactly after ⁵ / _e period from the previous current circuit a conclusion on α, β follows. Because after ^χ / ₃ + ^χ / ₂ period the current flows in the opposite direction as that in the winding P ¹ through P ² , because the voltage between a-ß is the same as, but only opposite to that previously prevailing between γ and α. With every ⁵ / _c rotation, double impulses result from the openings and closings with reversed magnetization; the following pulses have reversed polarities in the coil, but usually the arrangement is such that they enter the load in a single direction. This is done by means of a selector which reverses the connections ^{with every x} / ₆ rotation, ie every ⁵ / _{e period.} Ρατενί-Αν Proverbs: 1. Device for converting three-phase currents into rectified High-voltage currents, especially for the operation of X-ray tubes, by means of a transformer connected to an ordinary Three-phase network is connected with or without a neutral conductor, characterized in that that by a synchronously rotating switch the primary currents follow one another so that in the iron core in three successive magnetic reversals occur in each period, each of which generates an induction current in the secondary side generated so that a secondary alternating current with three times as high a frequency as that of the primary current arises, which is rectified to consumption by a rotating switch. 2. Device according to claim 1, with a transformer of high transformation ratio and a rotatable mercury beam interrupter driven by a synchronous motor, which makes a revolution every two periods and is isolated with six offset from one another by 60 ° Slats are provided with which the interrupter is in a beam or in two around 6o ° offset rays interacts, characterized in that around the iron core The coil has six primary windings connected in series in pairs and their three connection points the three lines of the network, while the free ends are each two diametrically opposite lamellae of the lower ship. 3. Device according to claim 1 and 2, characterized in that the interrupter motor drives a high-voltage switch connected between the coil and the consumer device, which consists of a cage of three columns (1, I ¹ ) arranged at the corners of an equilateral triangle and an isolated central axis connected to the shaft of the synchronous motor (A Fig. 2 ), which consists of two ίο groups of three radial metal arms (m, n, p, m ^l , n ¹ , p ^x ) offset from one another by I2O ° with metal hub (k) and insulating arms (i) between them with conducting through axially parallel conductors {x, y, z) connected heads (a, b, c, a \ b ^x , c ¹ ) are provided, which are opposed to conductive arc pieces Ui f> hi ^ ¹ ) ^on the pillars, where the connections are made at every sixth of a revolution reversed between the secondary side and the consumer device and only rectified currents are conducted in the latter. 4. Device according to claim 1 for operating a transformer with four-phase currents with a neutral conductor (with * / ₄ period phase shift to the neutral conductor) after conversion from three-phase current, characterized in that the rotating breaker with a mercury beam circulating once every three periods with motor drive and four lamellas is provided, which is at the poles of the \ ^? Phase voltages lie, while the neutral conductor is connected to the rotating beam via the primary winding of the transformer, in such a way that successive currents interrupted by a long pause are produced in the primary winding, which are reversed with each subsequent current circuit, with a high-voltage switch connecting the connections reverses between the secondary side and the consumer with every quarter turn. , 5. Device according to claim ι with rotating mercury beam interrupter with six lamellas, characterized in that the contacts are on the three phases' and a single primary winding of the transformer is connected between the beam and the neutral conductor, such that each phase successively flows into the primary coil sends that will be reversed after each interruption, said motor all five periods makes one revolution, so that each phase by _^5/6 period occurs in activity from the previous from and wherein the change to the high voltage of the secondary side by means of the high voltage switch for all ¹ J ₆ circulations take place. 6. Set up after. Claim 1 without a neutral conductor, characterized in that the primary side has three windings which are connected on one side to the three phases and on the other side to the three groups of opposing lamellae in such a way that by means of two beam arms offset ^{by 60 c, the} two lamellas hit at the same time, the voltage between two phases in both windings is initiated and interrupted. 7. Device according to claim 1, characterized in that the voltage between each phase and the neutral conductor after certain time intervals alternately and in the opposite sense in the one or another primary winding is conducted. 8. Device according to claim 1, characterized in that in connection with the high voltage selector, a transformer with a single primary winding provided with one end to the simple beam of a mercury breaker is connected with six lamellas and the other end to the center point that serves as the zero point of three coils that correspond to the three phases one including the neutral pole seven-pole transformer, whose six other poles go with the six Interrupter blades are connected, the mercury beam of the interrupter being driven by a three-phase motor is kept in circulation, which makes one revolution every two periods. 9. Device according to claim 1 and 8, characterized in that a single one Primary winding on the one hand to the neutral conductor and on the other hand to the diametrically opposite ones Beam arms of a 10c Ouecksilherunterbrechers with three lamellas are connected, each of which with one Phase is connected, the three-phase motor rotating the beam all makes one revolution for five periods. 10. Device according to claim 1, 8 and 9, characterized in that the two leads of each winding of a transformer with three primary windings each with two successive lamellae of a mercury double jet interrupter is connected, the three-phase drive motor of which one rotation every five periods power, with the three phases connected to one end of each of the three primary windings are. 1 sheet of drawings.