DE542963C - High vacuum switch for high performance - Google Patents

Description

It is known that the performance of switches is significantly increased when the contacts are separated in a high vacuum. For alternating current it has turned out to be Proven to be useful for the contacts, a material with a low melting point, such as Copper, to choose, for direct current, on the other hand, a material with a high melting point, such as Tungsten to be provided. Apart from the choice of the contact material, however, the switching capacity is important also highly dependent on the quality of the vacuum. The need to move the switching movement into the interior of the To transfer the vacuum vessel, now requires the use of elastic wall parts, which are particularly at their melting points tend to leak. The melting points of the fixed contact rods are also due to the weight of the leads and the shocks occurring when switching are particularly at risk. This is the case in particular in switches for large capacities where, because of the high currents to be carried, the Supply lines must be dimensioned particularly strong and therefore also a correspondingly be heavy. Due to the large masses to be moved, the stresses on the melting points are reduced continues to increase.

The masses to be moved during switching can, in a known arrangement, at the fixed contacts inside the vacuum vessel by one from the outside movable current bridge are bridged, therefore kept small because of all moving parts are only used by the power bridge to the power line. By the switching movement however, shocks still occur in the fixed contacts, which are their melting points can easily endanger.

According to the invention these disadvantages are eliminated in that the fixed contacts in the interior of the \ ^r akuumgefäßes firmly supported in such an arrangement, and are elastically connected simultaneously to the insertion sites with the vacuum vessel. A glass tube is particularly suitable as a seal for the cable entry of the stationary contacts, which is connected in a known manner with two metal sleeves, one of which is welded to the wall of the vacuum vessel and the other to the supply line, the sleeve being made of a metal with approximately the same coefficient of thermal expansion as glass. This makes it possible to fuse the metal parts with the seal and thus create a tight and durable union that is at the same time elastic enough not to transmit mechanical impacts to the walls. Furthermore, it is useful, the role of the movable contact to their

To arrange the axis freely rotatable and pivotable about an axis perpendicular to it, so that it lies easily between the contacts without kinking or edging, so that this also avoids switching surges as far as possible.

In Fig. Ι a switch according to the invention is shown, ι denotes the existing metal and two-part Vaxo vacuum housing, in the interior of which on a plate 2 serving as a contact carrier insulators 3 are attached. The two contacts 4 and 5, which are preferably made of copper, are attached to the rods 6 which serve as a power supply and which in turn are removed by the insulators. Each insulator is provided with a protective hood 7 which protects it from metallic deposits which could cause flashovers. The opposing contact surfaces 8 are inclined at right angles to one another and, when the switch is closed, are bridged by the movable contact 9, which consists of a roller movably attached to the end of the switching rod 10. It has been shown that with vacuum switches the sliding movement of the contacts on one another requires greater forces than, for example, with air switches. The cause is probably the fact that there is no air membrane between the sliding surfaces of vacuum switches. The arrangement is therefore made so that the sliding movement between the contacts needs to be as small as possible. The contact surfaces of the two contacts 4 and 5 are, therefore, inclined at 45 ° g ^s g ^s, the moving direction of the contact roller 11 and accordingly form together a right angle. Since the contact surface of the roller 11 forms a cylinder, the roller aligns itself and rolls on the two fixed contacts. An example of the movable attachment of the roller to the contact rod 10 is shown in FIG. In the fork 12, which is attached to the end of the contact rod 10, an axis 13 is guided, which contains a ball 14. The roller 11 is pushed onto this ball and is held by the plate 15 in such a way that on the one hand it can rotate about its axis and at the same time a limited movement is possible about an axis perpendicular thereto. The contact rod 10 is passed through the bottom of the vacuum vessel 1 in a vacuum-tight manner using a corrugated tube 16 and has a guide 17 inside the housing.

To actuate the movable contact, a drive device is provided, such as it is applied similarly to quick switches. It consists of the lever 30, which is about an intermediate member 31 is rotatably connected to the contact rod 10, and a spring 32, which moves the movable contact against the tensile force of a holding magnet 37 in the switch-off position is looking to bring. The holding magnet has a holding winding 38 fed by a direct current source 43 as well a trigger winding 39, which is arranged on two in counter-circuit and via one Resistor 44 connected to current transformers 41 and 42 is connected. The primary windings the current transformers are in the course of the line to be interrupted by the switch. A direct current flows through the secondary windings of the current transformers and at the same time the tripping winding 39, the size of which can be adjusted by a limiting resistor 45. A closing coil is used to close the switch 35, which acts on the switch linkage via a lever 33 and whose circuit ^ is closed by an actuating switch 48 can be.

To close the vacuum switch, the winding 38 of the holding magnet is first go excited, then switch 48 closed. This lifts levers 31 and 30, until the anchor attached to the latter touches the holding magnet 37, where it is held will. The contact point 11 now does not touch the fixed contacts 4 and 5, but only when the switch 48 is opened again, the spring 32 den Lever 31 turns clockwise.

Since the two current transformers 41 and 42 by the in their secondary windings flowing direct current is pre-magnetized and their secondary windings are switched against one another are, every abnormally high current wave in the main circuit, regardless of how it is directed, will in any case be one Cause a current surge in the same direction in the triggering winding 39. The latter is now arranged so that the current surge the power flow from the armature of the holding magnet in the Pole space shifts in, so that in this case by the spring 32 of the armature torn off and the lever 31 is pulled down. The switch contacts begin also instantly separate and move into the open position at great speed the switch brought. Since the moving contact consists only of the roller 11, which is only relatively small and light together with the shift rod 10, so In consideration of the small masses to be moved, a high switching speed

reached. The fact that the switching path of the movable Contact only needs to be very small and that special auxiliary or burning contacts except for the main contacts are not required. Since furthermore the contacts of the switch are not oxidizing, but are more likely to be subject to reducing influences, the contact surfaces remain smooth and

ίο clean. As a result, you can get smaller Use contacts than with the usual switch types, where the contact surfaces of the Are subject to pollution and burn-up.

L ^T m to maintain the vacuum in the switch housing, you can connect an evacuation device, similar to that used with large rectifiers. This facility consists in the present case, for. B.

from a backing pump 50 and a mercury vapor jet pump, which by a Pipe are connected to the switch housing. A vacuum measuring device can be used to assess the quality of the vacuum at any time Install 53 of a known type.

With regard to the special importance that the vacuum has for the operational safety of the Switch, it is important to have the bushing parts for the power leads like this to seal that they are safe in the rough handling of a switch in operation is exposed, does not suffer damage and does not give rise to leaks. With this in mind, the bushings are designed so that the sealing points are relieved of the impacts that occur when the switch is operated.

As shown in Fig. 1, the seal consists of a metal cylinder 55 which is tightly fastened in the side opening of the housing. The insulating tube 56, which is preferably made of glass, is fused on the one hand to the cylinder 55 and on the other hand to the closure piece $ γ , which is designed in the manner of a cap and which is tightly attached to the short, rigid piece 58 of the line 60. The parts 55 and 57 are made of copper or some other material, the thermal expansion of which is approximately the same as that of the tube 56 made of glass. A flexible piece 59 in the conduit allows slight movement of the part of the conduit 60 and located inside the vacuum housing prevents temperature stress. In order to avoid damage to the sealing points, the outer connection parts 60 of the lines are rigidly attached to the housing. For this purpose, a hollow insulator 61 is provided which, on the one hand, is carried by the housing and, on the other hand, is connected to the line end 60 through the metal sleeve 62. A second flexible conductor piece 63 is arranged between the parts 58 and 60 in order to protect the seal from mechanical stresses from the conductor carrier. The space between the insulator and the seal is expediently filled with oil that serves both for insulation and for cooling.

The embodiment described relates to a switch for alternating current. However, the switch can also be used for direct current if the contacts are made of a material with a high melting point, such as B. tungsten, are produced and instead of the release device described one is provided for direct current.

Claims (4)

80 claims: 1. High vacuum switch for large capacities with two fixed ones, with the Connected supply lines and bridged by an externally movable current bridge Contacts, characterized in that the fixed contacts are firmly supported in the interior of the vacuum vessel and at the same time are elastically connected to the vacuum vessel at the insertion points. 2. High vacuum switch according to claim i, characterized in that the seal for the cable entry consists of a glass tube (56) which is connected in a manner known per se with two metal collars (55, 57) made of a metal with approximately the same coefficient of thermal expansion as glass, one of which is welded to the wall of the vacuum vessel, the other to the supply line. 3. High vacuum switch according to claim ι and 2, characterized in that that the sealing sleeve (56) inside as a carrier for the outer connections is arranged serving and filled with an insulating liquid insulator. 4. High vacuum switch according to claim ι to 3, characterized in n ° that the roller of the movable contact is freely rotatable about its axis and pivotable about an axis perpendicular thereto is arranged. 1 sheet of drawings