DE3623994A1 - Busbar quick-action short-circuiting switch and/or earthing switch - Google Patents

Abstract

A busbar quick-action short-circuiting switch and/or earthing switch is equipped with a drive device, which has an energy store, and with a pressure sensor (22) which responds to a rise in pressure and is in the form of a cylinder/piston unit. The switch is arranged together with the pressure sensor (22) in the closed housing (1) of a switching device which contains insulating gas. The piston of the pressure sensor (22) is furthermore designed without any seal and has an amount of play with respect to the cylinder (20) which is sufficient to enable slow pressure equalisation between the interior of the cylinder/piston unit and the environment. <IMAGE>

Description

The invention relates to a busbar quick short circuit and / or earthing switch, which the features of the preamble of claim 1.

In encapsulated switchgear containing an SF ₆ filling as insulating gas, it is essential to prevent the overpressure from reaching the bursting limit of the housing when an arcing fault occurs and then the SF ₆ gas escaping. The known solutions already proposed for this are associated with a number of shortcomings. For example, they require a passage through the housing wall, which can cause sealing problems. Insofar as they evaluate the pressure difference between internal pressure and external pressure, the drive of the short-circuiting and / or earthing switch can be triggered in the event of a pressure increase in the interior of the housing, for example as a result of heating which is not caused by an arcing fault.

In a known switch of the type mentioned (DE-AS 25 05 158) for an air-insulated switchgear, it is known to provide a longitudinally displaceable piston in a cylinder as a sensor, which releases the drive device of the switch during a displacement. In the bottom of the cylinder containing this piston, a nozzle is provided to enable a pressure equalization when the pressure rises, which is comparatively slow compared to the pressure rise when an arcing fault occurs. External interference, such as the bang of an aircraft flying at supersonic speeds, cannot trigger the switch.

The invention has for its object to provide a busbar Quick short circuit and / or earthing switch for an encapsulated Switchgear create not only minimal delay of the switching process when an arcing fault occurs lets, but above all not by a sturgeon arc-induced pressure increases is insensitive, nevertheless but even then its high responsiveness does not ver if it is without maintenance and for periods of several Years need not take effect. This task solves a busbar quick-close and / or earthing switch with the features of claim 1.

As a result of the arrangement of the pressure sensor inside the encapsulation there are no sealing problems. Since the piston with play in Is guided cylinder, that is, a gap between the piston and the Inner cylinder wall is present when the pressure rises the encapsulation, which is not due to an arcing fault  is and is therefore much slower than the pressure increase in the event of an arcing fault in the one sealed off by the piston Interior of the cylinder balances pressure with the environment of the Cylinder so that in this case the piston is not or at least not so far that a switching operation is out is released even though the piston hits the Differential pressure between the inside of the cylinder and its um appeals. Because the piston because of the required play does not wear a sealing ring, is also particularly easy Way ensured that even after years of unchanged Po The piston is not stuck in the cylinder what can come between the piston and the cylinder inner wall would increase the piston response time. The piston is therefore maintenance-free and maintains its high sensitivity over long periods of time.

In a preferred embodiment, the Switch drive with a longitudinal displacement of the piston Means of claim 2, which to the lowest possible Ver delay in triggering the switch.

This is despite the high sensitivity of the pressure sensor Shocks as they can occur inside the encapsulation for example when the load or power scarf is actuated ter, not to trigger the quick-short and / or Er can lead switch, preferably the cylinder has egg ne shockproof arrangement, which advantageously according to An saying 3 is realized, since he no additional effort is required.

To prevent the occurrence of an arcing fault inevitable deformation of the housing's operability of the quick-close and / or earthing switch or even eliminated, are advantageously not only the moving union contacts of the switch, but also the fixed con beats arranged so that their position relative to each other not changed if the housing is deformed. This accomplished one advantageously with the features of claim 4.

In the following the invention with reference to one in the drawing illustrated embodiment explained in detail. It shows gene

Fig. 1 a fragmentary and partly schematic sectional Darge presented an encapsulated switching installation,

Fig. 2 is a Led parallel to the sectional plane of FIG. 1 th, are also incomplete and partial schematic section schematically shown, but in an opposite compared to Fig. 1 view Rich tung,

Fig. 3 shows a longitudinal section of the pressure sensor.

An encapsulated switchgear has a gas-tight, metallic housing 1 , which is filled with SF ₆ gas as an insulating agent. The housing 1 contains circuit breakers 2 , which could also be load switches. This power switch 2 are in several mutually parallel rows with their lower end at the bottom 1 'of the housing, because in the embodiment, the cable 3 of the network, in which the switchgear is included and which has an operating voltage of 30 kV in the embodiment to the Soil 1 'introduced the. The connection to the circuit breakers 2 is made via cable connectors and bushings.

All circuit breakers 2 , which are assigned to the same phase of the network, are connected in the region of their upper end to a busbar 4 , one end of which abuts the central section of a rail 6 and is connected to it in an electrically conductive manner. The rail 6 is, as shown in FIG. 1, from the section on the Sam melschiene 4 section up and then out again. The downward-facing end section carries a fixed contact piece 5 . The other section of the rail 6 is angled downwards and there mechanically firmly connected to an isolator 7 , which on the other hand is fixed in a carrier rail 8 , which is welded to the inside of the housing 1 and therefore, like the housing 1, is at ground potential. The isolator 7 isolates the rail 6 and the busbar 4 and the fixed contact piece 5 from earth potential.

The circuit breakers 2 of the other two phases are connected in the same way to a busbar, which are designed and arranged like the busbar 4 and how they each carry a fixed contact piece. Otherwise, the parts assigned to these two phases do not differ from those described above.

As shown in FIG. 2, above the insulators 7, a switch shaft 11 of a quick-closing and / or he earthing switch 12 with a horizontal longitudinal axis is rotatably mounted about the height of the fixed contact pieces 5 in the cheeks 10 fixed on the wall of the housing. On each of the fixed contact pieces 5 a from the scarf terwelle 11 radially projecting pair of switching knives 13 is aligned, the two switching knives of which, when the switch is closed, receive and contact the fixed contact piece 5 between them. In this switching position of the switch shaft, all busbars 4 are therefore short-circuited and moreover, since the switch shaft 11 is at ground potential, also grounded.

For the drive of the switch shaft 11 , a spring-loaded drive 14 is provided, which engages on a drive lever which is located on the switch shaft 11 . The device for tensioning the spring-loaded drive 14 is not shown. It has, like the drive device for the circuit breaker 2, a rod which is passed through the top of the housing 1 in a gas-tight manner. As shown in Fig. 1, from the switch shaft 11 is a locking lever 15 in the radial direction, one of the cutting edge executed longitudinal edge in the region of the free end of this locking lever 15 abuts a so-called half shaft 16 when the switch shaft 11 is in the off position and the spring-loaded drive 14 is tensioned. The half shaft 16 has for the engagement of the locking lever 15 an axial extension 16 ', which has a circular segment-shaped cross section, as shown in FIG. 1. Therefore, the locking lever 15 is released when the half shaft 16 is rotated a few degrees counterclockwise in a viewing direction according to FIG. 1. With the half shaft 16 lying parallel to the switch shaft 11 , a first lever 17 of a lever gear is connected in a rotationally fixed manner, which engages with a pin in an elongated hole of a second lever 18 which is pivotally mounted in the cheeks 10 about an axis parallel to the half shaft 16 , which are fixed to the inner wall of the housing 1 . The other arm of the double-armed second lever 18 is provided with a longitudinal slot open towards its free end, into which a cross pin 19 engages. Both this cross pin 19 and the pin projecting from the first lever 17 engage in the recesses in the second lever 18 which receive them without play.

In the amount of the upward-facing end of the second lever 18 is fixed to the support parts connected to the housing 1 , one end of a cylinder 20 which, as shown in FIG. 3, forms a pressure sensor 22 together with a piston 21 arranged longitudinally in it . As Fig. 1 shows the longitudinal axis of the cylinder 20 and thus the direction of displacement of the piston 21 extends perpendicular to the longitudinal axis of the switch shaft 11 at a distance above the latter. As a result, the pressure sensor 22 is shockproof against the vibrations caused by the actuation of the circuit breaker 2 . As especially FIG. 3, the piston 21 is disposed on one end of a piston rod 23 fixed slidably hinduchgeführt of Zylin through the bottom DERS 20 and carries in its other end portion of the transverse pin 19. The piston 21 is formed by a relatively thin disk in order to keep its mass as low as possible. The lowest possible mass of all parts to be moved by the piston 21 is also advantageous and is therefore provided. The Mantelflä surface of the piston 21 is, as shown in Fig. 3, crowned. Fer ner is the maximum diameter of the piston 21 selects slightly smaller than the inner diameter of the cylinder 20th As a result, there is a gap between the piston 21 and the inner wall of the cylinder, which allows pressure equalization between the interior of the cylinder 20 and the environment. Of course, the water gap is chosen so small that such pressure equalization does not occur or does not occur to any appreciable extent when an arcing fault occurs. Since the piston 21 is designed without a piston ring or device ring, the pressure sensor 22 is not only inexpensive. Above all, this ensures that, even when the piston 21 has been standing still for years, it cannot come to a sticking in the cylinder 20 . A surrounding the piston rod 23 and on the one hand on the piston 21 , on the other hand at the bottom of the cylinder 20 helical compression spring 24 with low pressure force leads the piston 21 after a switching operation back to the starting position shown in Fig. 3, which is a prerequisite for the locking lever 15 can come back into contact with the extension 16 'of the half-wave 16 .

In the event of a pressure rise in the housing 1 caused by an arcing fault, the differential pressure between the inside of the cylinder 20 and the surroundings of the piston 21 moves to the right at a value which is far below the bursting pressure when looking in accordance with FIGS . As a result, the second lever 18 is pivoted and the half shaft 16 rotated so far that the locking lever 15 is released . So that the Federspeicheran drive 14 can rotate the switch shaft 11 and bring the switching knife pairs 13 in contact with the associated fixed contact pieces 5 . The time until contacting the fixed contact pieces 5 is less than 100 ms and is therefore sufficient to extinguish the arcing fault before the pressure in the housing 1 has reached the burst pressure. Since the fixed contact pieces 5 are connected mechanically to the side wall of the housing 1 supporting the switch shaft 11 , bulging of this wall as a result of the excess pressure does not result in the distance between the switch shaft 11 and the fixed contact pieces 5 being increased.

All mentioned in the above description as well as the only characteristics that can be inferred from the drawing are white tere embodiments of the invention, even if they not particularly emphasized and especially not in the An sayings are mentioned.

Claims (4)

1. busbar quick-closing and / or earthing switch with an energy storage device Antriebsvor direction and a responsive to a pressure rise pressure sensor in the form of a cylinder-piston unit, the interior of which is connected to the surroundings of the unit via an opening, the Cross section is significantly smaller than the area of the piston exposed to the pressure of the environment, characterized in that it is arranged together with the pressure sensor ( 22 ) in the closed housing ( 1 ) of a switching device containing insulating gas and the piston ( 21 ) of the pressure sensor ( 22 ) executed without a seal and has sufficient clearance with respect to the cylinder ( 20 ) to form the opening. 2. Switch according to claim 1, characterized by a lever gear ( 17 , 18 ) which converts the longitudinal displacement of the piston ( 21 ) into a rotary movement of a first shaft ( 16 , 16 ') which has a section ( 16 ') in which the cross section of the shaft is reduced to a segment of a circle, and that this section ( 16 ') lies in the pivoting range of a lever ( 15 ) which projects from a second shaft ( 11 ) lying parallel to the first shaft ( 16 ). 3. Switch according to claim 1 or 2, characterized in that each of its existing movable contact pieces ( 15 ) is provided on a drive shaft ( 11 ), the longitudinal axis of which is probably that of the piston ( 21 ) and the direction of actuation in the housing ( 1 ) arranged load or circuit breaker ( 2 ) crosses. 4. Switch according to claim 3, characterized in that the movable contact pieces ( 13 ) are designed as a knife, the drive shaft ( 11 ) between a wall of the housing ( 1 ) and the existing fixed contact pieces ( 5 ) is arranged and the latter via at least one Insulator ( 7 ) are rigidly connected to this wall of the housing ( 1 ).