DE1273661B - Vacuum switch - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY GERMAN 4m? Wm> PATENTAMT Int. CL:

HOIh

EDITORIAL

German class: 21c -35/09

Number: 1273 661

File number: P 12 73 661.7-34 (G 42189)

Filing date: December 4, 1964

Opening day: July 25, 1968

The invention is based on a vacuum switch for switching off high alternating currents a magnetic field penetrating the arc gap between the switch contacts.

It is already known from French patent specification 1 257 305, a vacuum switch in which a radial magnetic field is generated in the space between the switch electrodes, which that is, perpendicular to the longitudinal direction of the arc burning between these switch electrodes.

The invention is based on the object of designing vacuum switches so that they are larger Able to interrupt currents than before.

The characteristic of the invention is that the magnetic field runs in the axial direction, its Lines of force are thus oriented parallel to the longitudinal axis of the contact opening arc and are controlled in this way becomes that it is strong during the period when the arc current is high, on the other hand, it is very weak during and shortly before the passage of the current.

In one embodiment of the invention, a coil surrounding the switch tube with the Switching electrodes connected in series.

In a further embodiment of the invention, the coil should have a saturable magnetic core contain a high proportion of the magnetic flux developed by the coil at low arc current values by way of a path remote from the arched section.

In the drawings shows

F i g. 1 shows a section of a vacuum switch according to an embodiment of the invention,

Figure 2 is a perspective view of a contact used in the switch of Figure 1;

Fig. 3 shows the arc voltage (peak value) depending on the peak arc current with magnetic induction as the parameter for a switch according to FIG. 1 and 2,

4 shows another embodiment of the invention,

FIG. 5 shows a section of the switch according to FIG. 4 along the line 5-5 in FIG. 4 and

Fig. 6 is a diagram that certain while a switching off process in the switch of FIG. 4 occurring electrical and magnetic relationships illustrated.

The switch shown in Fig. 1 has a highly evacuated chamber 10 consisting of a housing 11 made of suitable insulating material and two metal end caps closing the housing ends 12 and 13. Between the end caps and vacuum switch

Applicant:

General Electric Company,

Schenectady, N. Y. (V. St. A.)

Representative:

Dr.-Ing. E. Sommerfeld and Dr. D. v. Bezold,

Patent Attorneys, 8000 Munich 23, Dunantstr. 6th

Named as inventor:

Thomas Henry Lee, Nether Providence, Pa .;

Allan Nunns Greenwood,

Joseph William Porter, Media, Pa. (V. St. A.)

Claimed priority:
V. St. v. America 6 December 1963
(328 656, 328 601)

Suitable seals 14 are provided on the housing to make the chamber vacuum-tight. The atmospheric pressure in the chamber 10 under static conditions is less than 10 ~ ⁴ mm Hg, so that to some extent guarantee is given that the mean free path for the electrons is greater than the length of the gap in the chamber.

In the chamber 10 there are two disc-shaped contacts or electrodes 17 and 18 which are movable relative to one another and which are shown in their raised or open position. The upper, fixed contact is fastened in a suitable manner to an electrically conductive rod 17 a, which is connected at its upper end to the upper end cap 12. The lower, movable contact 18 is attached to a current-conducting actuating rod 18 a, which is mounted vertically movable in a suitable manner. The actuating rod 18 a passes through an opening in the lower end cap 13, an elastic bellows 20 made of metal seals the rod 18 a all around so that it can move vertically without impairing the vacuum prevailing in the chamber 10. As in Fig. 1, the bellows 20 is attached with its two ends in a sealing manner to the actuating rod 18 a or to the end cap 13.

809 587/412

3 4

A suitable actuating device coupled to the lower end of the actuating device with its outer circumference radially inward with general rod 18 a enforce a common spiral course, as in (not shown) guides the movable contact 18 F i g. 2 shown. These slots 32 force the current upwardly into contact with the stationary one at any point along the circumferential contact 17 so that the switch is closed. The contact closed position of the movable contact changes over to a path that is clocked in the vicinity by the dashed line 21. of the arc generally tangential to the circumference. The actuator pulls the contact 18 of the disc is directed. This tangential orientation also in the position shown in solid lines is shown in FIG. 2 back through the dashed line to open the switch. A der- io current path L, the one from the rod 18a to the light-like opening process, will be explained in the following detailed arc head 38 on the outer circumference of the contact. The axial length of the separator 18 guides is illustrated. This tangential gap with fully raised or separated conorientation of the current path has the effect that the cycle is typically 1.27 cm. magnetic loop L a tangential force component

By the arc (indicated at 38), which generates 15 nents that the arc in the circumferential direction Lifting the contacts over the separating gap 22 drives or presses tangentially around the contact. In the counter is pulled between these, some contact is made - according to Fig. 1 is the capability of the switch, "the at metal evaporates, and the resulting arc vapors generated by the high voltage shutdown distribute from the arc section 22 from condensing products, thereby considerably ver-Ui Direction to the chamber wall. In the 20 shown improves that at the arc gap 22 between Switches are the insulating inner surfaces of the device, an axial magnetic field 50 is applied to the contacts, housing 11 before the precipitation by the This axial magnetic field is controlled so that it Arc generated metal particles through a pipe during the period when the arc current Shaped metal shield 15 protected, which has a high value, is strong, on the other hand during and suitably held on the housing 11 and is very weak before 25 shortly before the current zero crossing. preferably from the two end caps 12 and 13. The axial magnetic field is generated by a coil 52

is isolated. This shield 15 catches the arcs generated by the cylindrical insulating housing 11 originating metal vapors and closes and in series with the circuit of the Schalkondensiert it before it is connected to the wall of the housing 11 diester so that the arc can be reached. To the possibility that part of the current flowing 30 also flows through the coil 52. Weh-fumes passed the shield 15 to rend the presence of the arc decrease, the circuit through the switch and the coil 52 are at the two ends of the middle one Shielding tube two front screens 16 and 16 a in front between two connections 54 and 56 on the seen. Rod 18 a, the contact 18, the arc 38, the

All inner parts of the switch are practically 35 contact 17, the rod 17 a, the connecting line table free of surface contamination. Additional 57 and the coil 52. When current flows through the coil The contacts 17 and 18 are effective from the 52, the magnetic field 50 is generated, its force-contact interior absorbed gases released so that lines generally parallel to the arc 38 in the a gas development from the contact pieces at the arc section 22 proceed.

Switching off high currents is excluded. 40 It has been found that the two contacts have the shape of a disk and are arcuate path of a vacuum switch with one of their main surfaces facing one another. strong axial magnetic field during strong In the middle area of each contact this main instantaneous currents developed arc voltage surface has a recess 29, which can be lowered very strongly by a. The energy, annular contact surface 30 is enclosed. 45 which the shielding during the arc-This ring-shaped contact surfaces 30 takes up the duration, the arc voltage is directly closed position of the lower contact (dashed proportional. By reducing this light-drawn position in Fig. 1) lie against each other, arc voltage at high current values will therefore have a such a diameter that the current flowing through the contacts determined by the energy entering the shielding is reduced by a correspondingly lowering and thereby the temperature rise, which is curved outwards in a loop, or the heating of the shielding follows path L , as correspondingly limited by the dashed lines in, so that the shield is indicated in FIG. This loop-shaped current capability, the path released from the arc gap, creates a magnetic effect that persists in condensing vapors, which, as is known, elongates the loop. This 55 In a test series with a switch in the has the consequence that when lifting the contacts under the training according to FIG. 1, but with coil 52 and surfaces 30 fed by a formation of an arc 38 between the separate direct current source, the magnetic effect of the loop was carried out, it was found that the light-shaped path following the current pushes the arc voltage peak radially outward with magnetic fields. 60 lawful strength is pressed down very hard

When the arc heads can hit the outside. The results of this series of tests are in circumference of the disks in a known manner 17 F i g. 3 shown graphically. You can see from this and 18 run, the arc 38 engages in a Um diagram that with a magnetic field of 6000 Gauss Magnetic force acting in the initial direction, the and current peaks of 50,000 to 60,000 amperes the Arc in the circumferential direction around the central axes 65 arc voltage quite considerably, namely on the discs pushes / This magnetic force is applied to about a third of the area without the magnetic field known way can preferably be depressed by a series of stepping values. With generated by slots 32, which the disks from lower magnetic induction and current

peaks in the range from 50,000 to 60,000 amperes, the arc voltage is not as strong is depressed, but even at a magnetic induction of 1600 Gauss, the lowering is the arc voltage is still almost as strong as 6000 Gauss. From the curves in FIG. 3 sees that the magnetic induction required for a given lowering of the arc voltage increases as the peak word of the arc current increases. You can also see that for For a given current value there is a value of magnetic induction, above which there is another The increase in the magnetic induction is only marginal in the sense of a further decrease in the arc voltage affects. For example, it can be seen from the curve in FIG. 3 that between 40,000 and 50,000 amps increases the magnetic induction beyond 1600 Gauss the arc voltage pushes very little further down.

In a preferred embodiment of the invention, the magnetic field 50 is made so strong that the arc voltages occurring during the current peaks to less than half of those Arc voltage, which would occur without the axial magnetic field, is suppressed. The invention however, it is not restricted to such an embodiment in the broader sense. For example can be used in cases where higher arc voltages are allowed with smaller magnetic inductions work. In any case, however, the applied magnetic inductions are large enough to a significant reduction in arc voltage for instantaneous currents greater than 20,000 amps to effect. For example, in one embodiment of the invention is a field generating Device provided that a magnetic induction of 800 Gauss in the arc gap 20,000 amps, 1,600 gauss at 40,000 amps and 2,400 gauss at 60,000 amps instantaneous current.

In order to increase the breaking capacity of a vacuum switch, it is not enough to just cover the arc section to apply a strong axial magnetic field that depresses the arc voltage peaks. Rather, it has been found that the presence of a strong axial magnetic field during the period when the alternating current is approaching the zero crossing, the breaking capacity The vacuum interrupter can seriously affect itself even if the arc voltage occurs during the peak of the instantaneous current has been depressed. It is therefore according to the invention the axial magnetic field is controlled so that it is during the current zero crossing and immediately before it largely disappears. It is not necessary that the axial magnetic field be critical during this Period disappears completely; however, its field strength should drop to such a low value that that the ability of the arc gap to withstand the repetitive voltage is negligible is less than it would be if during this interval around the zero crossing at all no axial magnetic field would be present.

Since the coil 52 in FIG. 1 is in series with the contacts 17, 18 of the switch, is of course the Coil current in phase with the arc current. However, this does not automatically guarantee that the magnetic field generated by the coil 52 in the arc gap or the associated magnetic flux is also in phase with the arc stream is. Rather, the eddy currents induced by the magnetic field cause them, except when they are on one be kept low, a considerable lag of the magnetic flux behind the current, what has the consequence that a relatively strong magnetic field remains on the arc section when the Current reaches zero. To reduce these eddy currents to such a value that the magnetic flux and the arc current are approximately in phase, the faceplate is made from one low-permeability material of high specific resistance, such as. B. corrosion-resistant steel, and also uses the slots 32 in the contacts 17 and 18 to create the eddy current paths in the Breaking contacts. With regard to this latter feature, the slots 32 are radially so far led inwards as possible in order to break open or separate the To achieve eddy current paths. In addition, each contact is in its central area 29 with holes or Perforations 70 (FIG. 2) are provided in order to further reduce the eddy currents. With such With reduced eddy currents, the magnetic flux can be sufficiently well in phase with the arc current are kept to in and immediately before the current zero crossing the magnetic field strength to be so small that the ability of the arc stretch to reduce the recurring tension Withstand zero crossing, is not significantly impaired.

As for its physical effect on the arc, the axial magnetic field prevents if its field strength is large, it is evident that the arc bends or curves and that the Arc products emerge from around the arc pillar. Through these effects the above-described lowering of the arc voltage occurs at high current values. On the other hand, if the field strength is very low, the magnetic field has no blocking effect on the arc products so that they easily emerge from the area of the arc section can. By making the axial magnetic field largely disappear when the arc current approaching its zero crossing, one therefore achieves that the arc products so can leave the area of the contact opening gap in time that the dielectric strength or insulation strength the arc section is restored to such an extent that the arc section of the recurring Voltage, which "begins to swing up" immediately after the current zero crossing, withstands.

Fig. 4 shows a vacuum switch design with additional facilities for influencing the density of lines of force of the axial magnetic field in the Arc gap.

In terms of construction, the arrangement according to FIG. 4 differs from that according to FIG. 1 mainly in that an iron core 60 is provided between the coil 52 and the insulating housing 11. This iron core 60 consists of a material of high permeability, for example silicon steel. Of the The core is made up of individual strips of grain-oriented silicon steel, which are evenly distributed over the circumference Packages 62 are arranged around the switch housing, constructed as best shown in

F i g. 5 sees. The individual packets 62 are peeled off due to high peak values such as 65,000 amperes Facilities such as B. a cylinder 63 tet. This peak current of 65,000 amperes was over made of insulating material, held together. about 50Vo- higher than the maximum peak current,

- When the current through the switch and the current through the switch are the same Series-connected coil 52 has a low 5 struktion, but without an axial magnetic field and without Has value, the iron core is 60 unsaturated, so that the iron core can be switched off, acts as a force line shunt path, which the greatest When the switch design according to F i g. 4 and 5

TeE of the magnetic flux generated by the coil 52 become the eddy currents in the same way as follows; so that only a very small proportion of magnetic flux is reduced in the embodiment according to FIGS. 1 and 2, gets into the arc gap. If the current flow io By this reduction in the eddy currents, the through coil 52 rises to a high value, the magnetic flux lagging behind the current the core saturates at a predetermined current - limited to such a small extent that at level, so that it is no longer a shunt for the current zero crossing, only a small magnetic flux in the that magnetic flux acts that remains through the predetermined arc gap, as in context Current values exceeding the th value are generated. A 15 with F i g. 1 and 2 explained in detail, high proportion of this generated by the overcurrent

Magnetic flux therefore occurs in the arc gap, a magnetic flux occurring at the current zero passage and permeates this, so that during the periods its amount even by considerable fluctuations high instantaneous current values in the arc gap on of the maximum flow during the high current periods axial magnetic field with high density of lines of force generated ao practically hardly influenced. That is, even if will. the flow maximum due to increased peak currents in

These relationships are illustrated in Fig. 6 - the coil rises considerably, this has just eased where the curve Φ wrestles the magnetic flux in the middle Zero current through a strong current flow, for example short-circuit current, 25 gear result. This is in FIG. 6 represented by the. This current is indicated by the curve I a dashed curve Φ _α , which represents the magnetic flux, which is plotted on the same time scale in the arc zone in those by the curve I _a as the curve Φ. Which represents the indicated increased currents corresponding to the curve /. If current is compared for the duration of a complete half- wave, the curves Φ and Φ _α can be seen plotted from O to C. Between the time - 30 that between the times A and B there is a stronger point O and A , the instantaneous curve is behaving - magnetic flux prevails in the contact zone when the current / _a is too low and the iron core 60 is unseeded. It should be noted, however, that tigt. The major part of the magnetic lines of force, which occurs shortly before the current zero point C, therefore runs through the core 60, and only a very small proportion of the lines of force, despite this increased flux maximum, reaches the ratio remains unchanged. This is the timing zone, as is the case with the relatively flat part, because the iron core 60 is unsaturated during the interval of the magnetic flux curve Φ between O and A, shortly before the current zero crossing. After the point in time A , the core 60 therefore begins to saturate itself from the main part of the contact zone, so that the additional current resulting from the increased instantaneous currents. H. the further increase in current, generated magnetic flux can subtract, flux in the core is no longer a way low magnetic flux. 6 that the density of lines of force

encounters resistance. A high percentage during the critical interval immediately before the start of this magnetic flux therefore occurs in the contact Strpmnullübergang the greater, the more the zone enters, which lags a considerably steeper rise in the magnetic flux behind the current (up to magnetic flux curve Φ corresponds . Shortly after the 45 about 90 °). This lag of the magnetic flux, current, reaches its peak value, also after the current, results, as already mentioned above, the magnetic flux, its peak value, and then together, mainly from eddy currents that fall off with the current. At time B , the magnetic field in the conductive components of the switching current has dropped to a value at which the ters are induced. In order to reduce these eddy currents on the iron core back to the unsaturated state beyond a tolerable level, the slots are designed so that the core has most of the magnet in the contacts radially as far as possible after the flow over one of the contact zone guided inside and can shunt way in the middle area of the contacts. It is true that the holes 70 also appear afterwards, as in FIG. 2 shows, the point in time in the contact zone a certain _, .- These slits interrupt or fragment the leakage flux component, which is, however, similar to the magnitude of the current paths for the rapidly changing current paths, such as the low, flat magnetic field 50 in the contact arrangement induced part of the magnetic flux curve Φ between the Zeitpunk eddy currents, while additional B and C indicated by the holes. borrowed resistances in the remaining eddy

In a practically tested switch construction, current paths are introduced. In addition, in the embodiment according to FIG. 4 and 5 was the iron 60 as mentioned above, the end caps 12 core 60 is designed so that it is at approximately and 13 to the eddy currents induced there 23,000 amps saturates. For currents over 23,000 Am - to limit values as small as possible, from one pere was the axial material of high specific resistance and never magnetic field occurring in the contact zone strong enough to reduce the arc voltage driger permeability such. B. corrosion-resistant to less than half the value of reduced steel. To the same end is the core adorn, which typically laminates without an axial magnetic field 60. By so doing the eddy currents on occurs. With a line voltage of 15.5 kilograms, the lag of the volt eff. With this switch currents with so magnetic flux behind the current were so low

The extent to which only a small amount of magnetic flux remains in the contact zone when the current passes through zero.

Tests carried out with a switch of the design described here have shown that that the force line density of the magnetic field remaining in the arc gap when the current passes through zero even after current peaks that caused 2000 and even 3000 Gauss in the gap, to less than 100 Gauss was limited. Such a weak magnetic field at and immediately before the current zero crossing is impaired the ability of the arc gap to withstand the recurring voltage is not noteworthy.

It should be noted that the magnetic circuit for the i'S the magnetic flux penetrating the iron core 60 around a large air gap or a large air gap encloses the outer periphery of the coil 52. This large air gap removes any residual magnetism reduced so far in iron that the controlling influence of iron on the density of lines of force in the arc zone on the polarity of the current flowing in the coil as well as on the previous magnetization states of the core is independent.

Although the core 60 is preferably arranged outside the housing 11, the core can also be in the Be arranged inside the housing, in such a position that the magnetic flux at low current values is deflected away from the arc path 22.

Claims (3)

Patent claims: 1. Vacuum switch for switching off high alternating currents with one the arc gap Magnetic field penetrating between the switch contacts, characterized in that that the magnetic field runs in the axial direction, so its lines of force are parallel to the longitudinal axis of the Contact opening arc are oriented, and controlled so that during the period in which the arc current has a high value, is strong, on the other hand during and briefly is very weak before the current zero crossing. 2. Vacuum switch according to claim 1, characterized in that a switch tube enclosing Coil is connected in series with the switch electrodes. 3. Vacuum switch according to claim 1 and 2, characterized in that the coil has a saturable magnetic core, which has a high proportion of the developed by the coil Magnetic flux at low arc current values over a distance away from the arc section Way closes. Considered publications:
German Patent Nos. 819 270, 474 379;
German Auslegeschriften No. 1203 349.1088 132; French patent specification No. 1344 824,
305 1 sheet of drawings 809 587/412 7.68 © Bundesdruckerei Berlin