DE3717864A1 - Vacuum switch - Google Patents

Abstract

In the case of vacuum switch housings, it is intended to reduce considerably the number of solder joints which have to be carried out in a vacuum-tight manner and also have to remain vacuum-tight over the entire operating life. The specified object is acheived especially by the following three measures: 1. A folding cup 30 is used for the vacuum-tight insertion of the movable current-conductor bolt into the vacuum switch housing. 2. The tubular connecting stubs on the wall of metal switching chambers or on the stationary current-conductor bolts are eliminated, together with their various covering and protection caps. A vacuum-tight plug 25 is fitted, instead of them, in the evacuation hole in the stationary current-conductor bolt. 3. Particularly in the case of insulating-material switching chambers, the metal-vapour condensation screens are eliminated and are replaced by ribs 18 on the inner surface. <IMAGE>

Description

Object and scope of the invention

The invention relates to switch housing of vacuum switches according to the Preamble of claim 1. The scope extends on the opening and closing of circuits in high-voltage networks and the current supply when the switch contacts are closed.

State of the art

A switch housing with the features of the preamble of claim 1 is known from the publication DE-PS 23 63 044. This switching The housing consists of an insulating hollow cylinder, the two end plates to lock. It penetrates through a central opening in one end plate the fully executed fixed conductor pin in the interior of the Switch housing.

The end plate on the other side has an even larger opening. At its edge, the corrugated sleeve, which is still open on both sides, is one Metal bellows soldered to one end. With the opposite The bellows is fixed to the end of a cap-shaped screen soldered. The screen is in turn with its central hole on the be movable conductor bolt pushed on and soldered to it.

Up to this point, the switch housing is already counting six critical solder joints.

Now there is a risk of leakage with soldered connections on a switch housing connected. Many critical solder connections therefore require a lot of effort Care is taken in their manufacture to minimize this risk hold.

The insulating hollow cylinder of the switch housing is approximately in the middle cross-divided to an annular disc as a carrier between the partial cylinders to be able to arrange a condensation screen. This increases the on Number of soldered connections to be kept vacuum-tight to eight, without this the maximum would have been reached. Rather, at least come two solder connections to be sealed against the vacuum, by  a penetrating the end plates of the hollow insulating cylinder Pipe socket through which the switch housing is evacuated. After the Eve the pipe socket is squeezed out to make it vacuum-tight close. Such a Eva still necessary according to the state of the art Kuiervorrichtung was probably in the drawing of simplicity omitted for the sake of it. However, it can be seen in the publication E-A 1 46 790. There is then also the considerable problem of the so-called "pump stengels ". Because of its fundamental nature, there are problems further, even if, as in US Pat. No. 3,727,018, the sensitive per se "Pump stem" relocated to the forehead of the fixed conductor pin becomes. Protective insulating caps and so-called shrink sleeves always either from the switch housing wall or from the conductor pin protruding evacuation pipe socket attached, can only be a gradual Bring improvement.

The number of soldered connections to be made and held has thus risen to at least ten. An even larger number of Such solder connections can switch housing with a central metalli the hollow cylinder and bushing on both ends Have isolators, as can be seen from the publication E-A 1 31 798.

Object of the invention

The object of the invention is to implement the number of vacuum-tight ones and to be kept vacuum-tight during the operating life of the switch housing Significantly reduce solder connections. With this task is subsequently also a considerable simplification of construction and manufacture of the switch housing connected.

A switch housing in an already considerably simplified design is already made known by the publication DS-OS 22 60 587. The simplification was achieved in that both switch contact pieces are symmetrical assigns to diaphragms which are attached to the current guide bolts seal the vacuum-tight housing at the front. " However, the following major problem is associated with such a construction:

Even - as used - two membranes only allow a very small switching stroke of two or three mm. In comparison, an opening stroke of 10 to 12 mm is necessary for a 12 kV vacuum switch. Added to this would be that with each membrane on the end faces of the switch housing, the contact drive force would also have to attack from both sides, which would result in a relatively very high level of design effort. The problem of the much too small diaphragm stroke, which is practically insoluble for the high-voltage vacuum switch housing, has already been at least hinted at in the much older publication DE-PS 4 07 725.

In this situation there are three subtasks.

The first subtask is to find a component that is a) similar a curved membrane is open on one side, b) like a bellows allows relatively large stroke and c) because of b) only on one side of the switch Housing needs to be arranged.

The second part of the task is to attach the evacuation pipe socket to the To eliminate switch housings.

The third subtask deals with the component condensation shield to make redundant.

Solution of the task

The object is achieved by the in claim 1 and in the independent claims 6 and 11 specified features solved. Advantageous further developments are due to the features in each assigned subclaims.

The solution is explained using two exemplary embodiments.

Embodiments

The figures to be explained below represent the following:

Fig. 1 longitudinal section of a medium-voltage switch housing in Iso lierstoff-enveloping cylinder type with metallic Endplat th and cross-fold cup bushing for the movable current conductor bolt; Associated circuit breaker nominal voltage: 12 kV.

Fig. 2 is a longitudinal section of a medium voltage switch housing in metal chamber single feedthrough insulator type and longitudinal folds cup through for the movable conductor pins; Associated load switch nominal voltage: 12 kV.

To Fig. 1: The switch housing A of a vacuum circuit breaker having a rated voltage of 12 kV, a rated current of 1250 A expectable and an expectable Nennkurzschlußausschaltstrom of 25 kA consists essentially of three modules. The upper end plate 4 belongs to the first assembly. The fixed current conductor bolt 5 with its wide flange 6 is soldered to the inside in a vacuum-tight manner. This conductor pin carries the contact body 7 ; In it - externally not visible - devices for excitation of an axial magnetic field are arranged.

The end plate 8 belongs to the second assembly. The bearing body 9 for the current conductor bolt 10 , 15 , which can be moved without rotation, and the transverse fold cup 30 are fastened thereon. The cap 12 secures the bearing body against axial rotation. On the bottom 13 of the cup outside of the switch space, the conductor pin section 10 with its radial extension 14 is soldered and on the vacuum side the conductor pin section 15 with its radial extension 16 . The extensions 14 , 16 can also be designed as separate disks and receive approximately the diameter of the cup base; for this purpose, the washer 14 must then be inserted and soldered in place. The third assembly is the insulating hollow cylinder 3 without an inner metal shield body. This eliminates a potential source of detachment and a dielectric risk of the metallic particles. For this purpose, ribs 18 are worked out only in the end regions of the insulating hollow cylinder. Seen from the switching arc, their leeward sides are practically spared metal vapor condensation. It should be borne in mind that a diffuse switching arc, in contrast to its contracted shape, generates very little metal vapor. In addition, as a result of international investigations of the switching frequency, the number of switch trips per year is very small; For example, with a nominal voltage of 72.5 kV, it is only 25 on average. According to this, a 72.5 kV vacuum switch would have an average of only 625 switch-offs over a period of around 25 years; and only a few of them are short-circuit current cut-outs. The front ribs go into a wall reinforcement 19 of the insulating hollow cylinder. This increases its resistance to pressure loads when the end plates are shrunk on.

The fixed conductor pin 5 is provided with a central longitudinal bore 20 , which branches into two bores with the same overall cross section 21 into the switch room to be evacuated. After evacuation, the hole is almost completely filled by a plug 25 made of electrically conductive material; this achieves the following:

• a) the electrical resistance of the tapped current decreases ladder bolt considerably;
• b) the thermal conductivity increases significantly;
• c) the plug practically welded to the bore wall absolutely vacuum-tight closure;
• d) can this stopper not be damaged.

For the introduction of the plug there are several possibilities: Z .B. a device working according to the extrusion process can be used for this. Or a rigid metal plug is pressed into the longitudinal bore 20 and welded to the bore wall by high-frequency induction heating. It would also be possible to fill in liquid metal. A fold sleeve, also not shown, is arranged between the filler insertion device, not shown, and the current conductor bolt with its longitudinal bore, so that the plug can be introduced under vacuum. From this manipulator, a connecting line branches off to the vacuum pump, not shown.

Finally, it should be pointed out that the vacuum Switch housing only four connections to be soldered vacuum-tight having.

To FIG. 2: The vacuum switch housing B with the metal chamber 50 and the single bushing insulator 40 is for the switch off and on 400-630 A designed load currents at a rated voltage of 12 kV.

Its movable contact piece 10 , 14 , 15 , 17 is drawn to the left of the center line when switched on and to the right of it when switched off. The bushing insulator 40 presses the fixed current conductor bolt 5 carrying the contact body 7 in a vacuum-tight manner. Then this guide is used in the pipe neck on the metal chamber part 41 and thus soldered vacuum-tight. The complementary metal chamber part 42 just has an approach. The edge region of the cup 44, which has a longitudinal fold 43 , is soldered onto its shoulder in a vacuum-tight manner. The ring 45 supports the cup rim from the other side. One side of the longitudinal fold leans against the wall of this set; the other side leans on the surface of the approximately cap-shaped extension 14 ; the cup base 13 is soldered to its forehead. On the vacuum side of the bottom, the partial current carrying pin 15 carrying the contact body 17 is fastened thereon. After this preparatory work, the two assemblies, ie the completed metal chamber parts 41 , 42, are pushed into one another and soldered; this completes the metal chamber 50 and switch housing B.

Claims (17)

1. Vacuum switch with

• a) a switch housing ( A ; B ), which is either formed from an electrically insulating material and on the end faces with electrically conductive end plates ( 4 , 8 ) provided hollow cylinder ( 3 ) or from a hollow cylinder ( 50 ) from electrically conductive Material on which a lead-through insulator ( 40 ) is arranged at least on one end face;
• b) two switching pieces ( 5 , 7 ; 10 , 15 , 17 ) arranged axially in alignment within the switching housing, one of which is axially movable;
• c) a concentric screen body attached to the inner surface of the hollow cylinder ( 3 ) made of electrically insulating material;
• d) a folding sleeve ( 11 ) for the vacuum-tight insertion of the movable current conductor bolt ( 10 , 15 ) into the switch housing;
• e) a tubular introduction into the switch housing for its evacuation; characterized by the following feature:
• f) for the vacuum-tight insertion of the movable current conductor bolt ( 10 , 15 ) into the switch housing ( A ; B ), a ------------ approximately cup-shaped body ( 30 ; 44 ) is the same or small on one end region Neren diameter, the side wall length can be changed by wrinkling, added concentrically and vacuum-tight with its edge area.

2. Vacuum switch according to claim 1, characterized by the following feature:
the side wall of the cup ( 30 ) has folds ( 11 ) which run approximately perpendicular to the center line by embossing at least one shaft. 3. Vacuum switch according to claim 1, characterized by the following feature: the side wall of the cup ( 44 ) has an approximately parallel to the center line running wrinkle formation ( 43 ) by everting. 4. Vacuum switch according to claim 1, characterized by the following feature:
the movable conductor pin ( 10 , 15 ) is composed of at least two partial bodies, of which the first partial conductor pin ( 10 ) on the outer surface of the cup base ( 13 ) and the second partial conductor pin ( 15 ) on its surface facing the vacuum and electrically conductive the first partial current conductor bolt is axially aligned 5. Vacuum switch according to claim 1, 4, characterized by the following feature:
at least one partial current conductor bolt widens in the direction of the cup base ( 13 ) to an area of larger diameter. 6. Vacuum switch according to claim 1, 4, 5, characterized by the following feature:
at least in the case of the partial current conductor bolt ( 10 ), the region of the larger diameter is designed as a separate body ( 14 ). 7. Vacuum switch according to claim 1, 4, 5, 6, characterized by the following feature:
the diameter of the body ( 14 ) is approximately the same as the diameter of the cup base ( 13 ). 8. Vacuum switch according to claim 1, characterized by the following feature:
the bottom of the cup ( 30 ; 44 ) has an approximately circular recess for centered fastening of the movable partial current conductor bolts ( 10 , 15 ). 9. Vacuum switch according to claim 1, characterized by the following feature:
the bottom ( 13 ) of the cup ( 30 , 44 ) has a central opening for the vacuum-tight passage of the movable undivided current conductor bolt ( 10 , 15 ), the diameter of which widens in the area of its attachment to the bottom surface in the manner of a flange. 10. Vacuum switch according to the preamble of claim 1, characterized by the following feature:
the fixed conductor pin ( 5 ) is provided with a longitudinal bore ( 20 ) which leads via at least one branch ( 21 ) into the interior of the switch housing ( A ; B ) and is filled at least partially and vacuum-tight after its evacuation by a filler ( 25 ) . 11. Vacuum switch according to claim 10, characterized by the following feature:
the filler body consists of metal, which in the plastic state is at least pressed into the longitudinal bore. 12. Vacuum switch according to claim 10, characterized by the following feature:
the packing consists of metal, which in the liquid state is at least poured into the longitudinal bore. 13. Vacuum switch according to claim 10, characterized by the following feature:
the filler body consists of a non-metallic material that is introduced at least into the longitudinal bore. 14. Vacuum switch according to the preamble of claim 1, characterized by the following feature:
the inner surface of the hollow cylinder ( 3 ) made of electrically insulating material or a bushing insulator ( 40 ) on a hollow cylinder ( 50 ) made of electrically conductive material is provided with rib-shaped projections ( 18 ) in planes approximately perpendicular to the center line. 15. Vacuum switch according to claim 14, characterized by the following feature:
in the end regions of the hollow insulating cylinder ( 3 ) or a guide insulator ( 40 ), the wall thickness ( 19 ), starting from the maximum extension directed towards the center line of the rib-shaped projection ( 18 ) to the front edge remains approximately constant. 16. Vacuum switch according to claim 14, characterized by the following features:

• a) the inner surface of the hollow cylinder ( 3 ) made of electrically insulating material or a bushing insulator ( 40 ) on a hollow cylinder ( 50 ) made of electrically conductive material has rib-shaped projections ( 18 ) only in some areas;
• b) at least one of the two contact bodies ( 7 , 17 ) is equipped with devices for exciting an axial magnetic field,

17. Vacuum switch according to claim 14, characterized by the following feature:
the rib-shaped projections ( 18 ) are arranged in the end regions of the insulating cylinder ( 3 ) or in the end region of a bushing insulator ( 40 ).