CH641292A5 - EXHAUST GAS SWITCH. - Google Patents

Abstract

1. Gas-blast switch having a tubular support insulator (12) being supported on a support housing (11) at ground potential and supporting in turn at least one switching chamber (13) the inner spaces of the support housing (11), of the support insulator (12) and of the switching chamber (13) being totally enclosed but in flow communication with one another and containing a pressurized quenching gas, said switch having further a quenching gas heating device (27) at ground potential, the device being in flow communication with the switching chamber (13) via the support insulator (12), characterized in that a connection line (35) leading from the switching chamber (13) and positioned adjacent the support insulator (12) extends to the heating device (17).

Description

The invention relates to a gas pressure switch of the type mentioned in the preamble of claim 1.

The purpose of the heating device provided for the extinguishing gas is to prevent condensation of the pressurized extinguishing gas and the associated reduction in its density and dielectric strength at low ambient temperatures.

Such gas switches are known for example from DE-OS 2825744 and from GB-PS 1229036. In these switches, the extinguishing gas heated by the heating device rises through the thermosiphon effect in a chimney-like pipeline running through the support insulator in the longitudinal direction to the switching chamber, while from this the cooler or the cooled gas in the between the inner wall of the support insulator and the outlet the wall of the pipeline that remains free again sinks towards the heating device. In the case of switches for comparatively high nominal voltages, the support insulators have respectable heights, so that an effective and sufficiently rapid circulation of the extinguishing gas heated by the heating device (without further aids) requires sufficient flow cross sections of both the pipeline and the jacket space. This in turn necessitates a larger dimensioning of the diameter of the support insulator than would be necessary due to its purely mechanical stress.

In another known switch of the type mentioned (US-PS 3749869), the switching chamber is supported horizontally on two tubular support insulators. The interior of the first of these support insulators only serves as an exhaust space for the switching gases and is only opened via a valve during a switch-off stroke. The interior of the second support insulator, on the other hand, also serves to supply the heated and pressurized quenching gas to the switching chamber and to return the cooler or cooled quenching gas from the switching chamber back to the heating device. The two flow paths in the interior of the second support insulator run directly next to one another and are not separated from one another by a partition. The heated extinguishing gas, which is further compressed by a blower or a compressor, is blown upward in a jet via a nozzle and the suction side of the blower or the compressor draws cooler or cooled quenching gas from the interior of the second support insulator at a location laterally adjacent to the nozzle .

It is obvious that the length of the flow paths can be very limited in this arrangement. Accordingly, this arrangement is not useful in high-voltage switches (with supporting insulators of considerable height).

Accordingly, a purpose of the present invention is to provide a switch of the type mentioned, in which a sufficiently rapid circulation of the extinguishing gas is formed without increasing the cross section of the support insulator due to the effect of the heating device, the length of the support insulator of this circulation hardly being stands in the way.

This purpose is achieved in the proposed gas pressure switch by the features specified in the characterizing part of patent claim 1.

Features of preferred embodiments can be found in the dependent patent claims and the following description of exemplary embodiments of the invention. It shows:

Fig. 1 shows a longitudinal section through a first, and

Fig. 2 shows a longitudinal section through a second embodiment.

In the drawing, the same reference numbers are used for functionally corresponding parts.

The pressure gas switch 10 shown has a support housing 11 which is at ground potential and on which a tubular, upright support insulator 12 is flanged tightly, the height of which essentially depends on the nominal voltage and also on the type of installation for which the switch 10 is intended .

The support insulator 12 carries a switching chamber 13 arranged vertically here, which is enclosed by a tubular insulator 14 and is sealed at the top with a connecting flange 15. Between the insulator 14 and the support insulator 12 there is a lower connecting flange 16 which is tightly connected to the insulator 14.

Arranged in the switching chamber 13 are a set 17 of fixed contact pieces connected to the upper connection flange 15 and a set 18 of movable contact pieces which are electrically connected to the lower connection flange 16 and to which a movable blowing nozzle 19 and a pump cylinder 20 are assigned. A push and pull rod 21 is coupled to the set 18 of movable contact pieces, which extends downward out of the switching chamber 13 and at the bottom to a push and pull tube 22 made of an Iso2

5

10th

15

20th

25th

30th

35

40

45

50

55

60

o5

Lierstoff is anchored, which in turn is coupled via a further rod 23 and a connecting rod 24 to a crank 25 of a drive, not shown. A compression spring 26 supported at the top in the support housing 11 and at the bottom on the rod 23 serves as an energy store for the switch-off stroke.

The switching chamber 13 and the interior of the support insulator 12 and the support housing 11 are sealed off from the outside, but are in flow communication with one another and contain an extinguishing gas under a pressure of about 5-20 bar, for example SF6. As already mentioned in the introduction, it is important to avoid condensation of the extinguishing gas at lower ambient temperatures with such switches.

For this purpose, a heating device 27 is provided which is electrically connected to the support housing 11 and is also connected to earth potential. In detail, this has a heating element, for example an electric heating coil 28, which is arranged in a tube section 29 open at the bottom. This pipe section 29 is arranged coaxially and with radial play in a cup-shaped housing 30 - preferably made of a material which is poorly thermally but sufficiently electrically conductive - and is connected at its upper end to a bend 31 to which a pipe leading radially out of the housing 30 is connected 32 is connected. The tube 32 leads to a radial bore 33 in the flange 34 of the support housing, to which the support insulator 12 is tightly attached. A flow connection line 35, which is arranged next to the support insulator 12 and parallel to the latter, is connected to the housing 30 at the top and establishes a flow connection between the heating device 27 and the switching chamber 13.

In the embodiment according to FIG. 1, this connecting line 35 has a first, tubular insulator 36,

one at the level of the lower connecting flange 16 and fastened to this via a strut 37, metallic connecting sleeve 38, and a second, next to the insulator 14 and arranged parallel to this, the tubular insulator 39, the upper end of which is provided with a metallic, with cooling fins 40 and a laterally protruding connector piece 41 is connected. The connecting piece 41 is connected in a manner not shown in detail tightly to a bore 43 leading radially out of the upper connecting flange 15, which in turn starts from the upper end of the switching chamber 13. It should be noted that, apart from the small pressure drop caused by the heating device 27 (when switched on), the switch extinguishing gas pressure is essentially the same everywhere in the switch 10 - be it in the switched-on or in the switch-off position shown.

In operation, the heating coil 28 heats this brushing 641 292

extinguishing gas, which in turn rises in the pipe 29 and at the same time draws further extinguishing gas from the connecting line 35 via the jacket space remaining between the housing 30 and the pipe 29 and the lower, open end of the pipe 29. The heated extinguishing gas passes through the pipe 32 and the bore 33 at the bottom into the interior of the support insulator 12 and rises through it and through the switching chamber 13, cooling more or less, depending on the ambient temperature. Through the bore 43 and the connecting piece 41, the somewhat cooled quenching gas now leaves the switching chamber 13 and reaches the connecting piece 42 provided with cooling fins, where it is cooled further. As a result, the gas now drops again in the connecting line 35 to the heating device 27.

Since heat is also generated in the switch chamber 13 when the switch is in the on position, depending on the current being conducted, the heating coil need not remain switched on continuously. Therefore, e.g. In the area of the lower end of the connecting line 35, a temperature sensor 44, only shown schematically, may be provided, which e.g. regulates the heating power absorbed by the heating coil 28 via a switch 45, e.g. switches on or off.

The essential difference between the embodiment of FIG. 1 and that of FIG. 2 is that the connecting line 35 in FIG. 2 only extends to the lower connecting flange 16. Accordingly, the connecting line 35 has only the tubular insulator 36 on which the connecting piece 42 is placed tightly. Its connecting piece 41 is connected to a passage 46 formed in the lower connecting flange 16, which in turn extends from the lower end of the switching chamber 13.

In both cases, an effective circulation of the extinguishing gas through the heating device is ensured (even if only the thermosiphon effect is used).

In the embodiment of FIG. 1, the entire switch is included in this circulation path. This embodiment is therefore particularly suitable for outdoor installation in areas where particularly low ambient temperatures are to be expected. The somewhat less complex embodiment of FIG. 2, on the other hand, is more suitable for installation in areas in which extremely low ambient temperatures are not to be expected.

Of course, the extinguishing gas circulation can be increased using known means, such as a pump or fan, which are not shown in the drawings. This increased extinguishing gas circulation can be advantageous both in extremely cold weather and when the compressed gas switch is under a high current load, in which case the heating coil 28 is switched off by the temperature sensor 44 and the switch 45.

3rd

5

10th

15

20th

25th

30th

35

40

45

50

G

1 sheet of drawings

Claims (7)

641 292 PATENT CLAIMS 1. Gas pressure switch with a tubular support insulator (12) on a support housing connected to earth potential (11) is supported and in turn carries at least one switching chamber (13), the interior of the supporting housing (11) and the supporting insulator (12) and the switching chamber (13) being encapsulated to the outside, but being in flow connection with one another and an extinguishing gas underneath Contain pressure, as well as with an extinguishing gas heating device (27) which is connected to earth potential and which is connected to the switching chamber (13) via the supporting insulator (12), characterized in that one of the switching chamber (13) is located next to the supporting insulator (12) arranged flow connection line (35) to the heating device (27). 2. Gas pressure switch according to claim 1, characterized in that the flow connection line (35) is essentially formed by one or more tubular insulators (36, 39) arranged parallel to the supporting insulator (12). 3. Gas switch according to claim 1, characterized in that the flow connection line (35) from the region of the support insulator (12) facing away from the end of the switching chamber (13) (Fig. 1). 4. Gas-blast switch according to claim 1, characterized in that the flow connection line (35) starts from the area of the end of the switching chamber (13) facing the support insulator (12) (FIG. 2). 5. Gas-blast switch according to claim 1, characterized in that means (29, 31, 40) are provided to allow the extinguishing gas to flow in the support insulator (12) from bottom to top and in the flow connection line (35) from top to bottom. 6. Pressure gas switch according to claim 5, characterized in that said means have a gas cooler (40) arranged at the upper end of the flow connection line (35). 7. Pressure gas switch according to claim 5, characterized in that said means have a in the lower region of the flow connection line (35) arranged, a heating element (28) containing tube (29), the lower end of which is open, and the upper end of which is via a bend (31) is connected to the lower region of the interior of the support insulator (12).