DE668045C - Surge arrester with spark gap, the arc of which is extinguished by flowing pressurized gas - Google Patents

Description

Surge arrester with spark gap, the arc of which is caused by flowing Compressed gas is extinguished In spark gaps with arc extinguishing by compressed gas According to the main patent, there is an electrode spacing that is most favorable for arc quenching, which is defined by the fact that at this distance the blowing effect between the Electrodes flowing through compressed gas is a maximum. If you now use such a Spark gap in surge arresters, the result is that the spark gap when the most favorable extinguishing distance is set, the response voltage is too low would have because the electrode spacing at which the arc extinction is most favorable is relatively small. So if you would use the spark gap on the cheapest Set the extinguishing distance, so under certain circumstances would already be with normal operating voltage Flashovers occur at the spark gap, which is of course impermissible. Provides on the other hand, the spark gap is set so that it only reaches the desired value the overvoltage responds, the electrode spacing is usually like this great that the compressed gas does not have its maximum blowing effect at the extinguishing point and the extinguishing performance of the compressed gas spark gap, which is very high in itself, is not can be used sufficiently.

In order to eliminate these disadvantages, two spark gaps are provided according to the invention connected in series, of those who blow a pressurized gas and to the cheapest Extinguishing distance is set while the electrode distance of the second spark gap, which has no quenching device, only with regard to the response voltage is dimensioned in such a way that the flashover voltage of the two spark paths together corresponds to the desired response voltage. This achieves that on the one hand, the surge arrester only when there is one due to the operating conditions overvoltage caused in the network responds and that, on the other hand, still has the advantage the high performance of pressurized gas-blown spark gaps is fully utilized.

It is indeed a surge arrester with two series connection Known spark gaps, one of which is used to heat the air in a housing serves, at the outlet opening of which the second air heated by the outflowing air spark gap to be extinguished is arranged. In this known arrangement, however, is neither can the extinguishing spark gap be set to the most favorable extinguishing distance, nor can it effective extinguishing can be achieved by the outflowing heated air, since this On the one hand air does not have a sufficiently high pressure and on the other hand due to the arc the auxiliary spark gap with Ion is saturated and heated and as a result do not cause any cooling or isolating locking of the electrodes in the extinguishing path can.

Instead of seeing a second spark gap vorrrix, you can also see that Make the electrode section of the compressed gas spark gap so variable that in the Rest state the spark gap to the response voltage corresponding to overvoltages Value is set and that after the response the electrodes are known per se Means are automatically approached to the most favorable extinguishing distance.

According to the first-mentioned embodiment, when two are connected in series Arranges spark gaps, so the spark gap not blown with compressed gas in a particularly simple way to control the compressed gas supply for the main spark gap with the help of the arrester current: This can be done in particular in the way that one encapsulates the auxiliary spark gap and the one caused by the arc Thermal expansion of the gaseous or liquid medium contained in the enclosure can act on the valve that the compressed gas supply line to the main spark gap controls. Exemplary embodiments of the invention are shown in the drawing.

Fig. I shows one consisting of two series-connected spark gaps Surge arrester connected to the line to be protected at i and to earth at 2 connected. One of the two spark gaps is provided with compressed gas extinguishing and trained according to the main patent. It has a nozzle-shaped electrode 3, which is carried by an insulating tube 4. The counter electrode 5 is pin-shaped and protrudes into the opening of the nozzle-shaped electrode 3. The electrode 5 is connected to the lower one via a `Viderestandsstab 6 ', which serves as an arrester resistor earthed terminating part 7 of the sheath 4 attached, which through a pipe 8 with the pressurized gas source connected is. With the nozzle-shaped electrode 3, one electrode is the auxiliary spark gap g connected, while the second electrode of a special post insulator io will be carried. The pressurized gas spark gap is set so that its electrode spacing has the most favorable value for arc extinguishing with compressed gas, while the Auxiliary spark gap g is set so that the flashover voltage of the total combination corresponds to the response voltage required for the surge arrester.

The arrangement works in such a way that when a corresponding Overvoltage the two spark gaps connected in series will break through and in a known manner a diverter current damped by the resistor 6 from the line to be protected flows to earth. At the same time, the hr 8 pressurizes gas that flows between the electrodes 3 and 5 and arcs here: extinguishes at the location set to the most favorable extinguishing distance, whereupon the arc at the auxiliary spark gap g extinguishes by itself and the arrester is ready to respond again.

In Fig.2 an embodiment is shown in which the auxiliary spark gap g is used at the same time to the compressed gas supply to the compressed gas spark gap to be controlled depending on the arrester current. The spark gap is used for this purpose g arranged in a closed envelope ii, so that due to the thermal effect of the between the electrodes g of the passing arc there is a sudden strong expansion the medium surrounding the electrodes, air, other gas or liquid, enters, which acts via a pipe 12 on an auxiliary valve i3, which in a manner known per se the main valve 14 located in the compressed gas supply line 8 responds. These Type of control of the compressed gas supply has the advantage that no special additional Apparatus are required, but rather the -.- production of a s-msprecnvoltage is available required auxiliary spark gap is made usable for this special purpose. Another advantage is that the control device has very little inertia possesses, so that from the moment of the rollover to the beginning, the compressed gas flow only a very short time passes on the electrodes 3, 3 and 5.

Fig: 3 shows a further embodiment, and in particular the application of the invention to a surge arrester for multiphase currents is shown here. Here, the three compressed gas spark gaps of a three-phase system are arranged on a common gas guide space 15 , while the auxiliary spark gaps connected in series with them sit in a common shell 16. As in Fig. Z and 2, the compressed gas spark gaps consist of a nozzle-shaped electrode 3, which is carried by an insulating tube 4. The latter is fastened in a power supply piece 17, which in turn is fastened to the gas supply space 15 via a further insulating tube 18. The pin-shaped electrode 5, the lower part 6 of which is made of resistance material, e.g. B. Silit, exists, is displaceably guided in the power supply piece 17 and extended through the gas supply space 15 by means of an insulating piece ig. At the lower end of the insulating piece ig engages a tab 2o which is rotatably fastened at 21. The guide piece 21 is common for all three phases and is attached to a tube which carries a piston 23 loaded by a spring 22. The hollow piston rod slides on a guide pin 24 and serves to move the electrodes 5 of the three compressed gas spark gaps away from their counter-electrodes 3 when the gas pressure drops so that the surge arrester does not respond in this state which is not suitable for effectively extinguishing the interrupting arc can be done. The gas distribution space 15 is connected via a valve 14 to the pressurized gas container 25, which forms the base of the entire arrangement and has a connecting piece 26 for the pressurized gas supply line.

The current-carrying piece 17, which is designed as a sliding contact, leads to the auxiliary spark gap lying in series with the gas spark gap, which, like already mentioned, housed together in the encapsulation 16 for all three phases are. A special spherical electrode 27 is provided for each three-phase phase, which, offset by i2o °, at a certain even distance from the earthed one common counter electrode 28 are arranged. The distances between the auxiliary electrodes 27, 28 are dimensioned here so that with the most favorable extinguishing distance of the compressed gas electrodes 3 and 5 the response voltage of the overall combination for the operation of the surge arrester has required value. From the housing 16 of the auxiliary spark gap leads, in the same way as in Fig. 2, a pipe 12 to the auxiliary valve 1ß, its actuation the opening of the main pressure gas valve 14 results.

When the surge arrester responds, an arc flashover occurs both between electrodes 3 and 5 and between 27 and 28 in the housing 16. Due to the thermal effect of the arc created between the electrodes 27 and 28 the medium located in this shell is heated, which increases the pressure Consequence. This pressure acts via the pipeline 12 on the. Auxiliary valve piston 13, which in turn brings the main valve 14 to open. As a result, that flows Pressurized gas from the container 25 through the chamber 15 to the three pressurized gas spark gaps, inflates their electrodes to the maximum and thereby extinguishes the arc. Once this has happened, the arc between the electrodes will also disappear 27 and 28, and the auxiliary valve 13 closes, whereupon the main valve 14 also closes returns to its closed position. To prevent getting between the auxiliary electrodes 27 of the three individual phases, when the spark gap responds, a flashover occurs, the three electrodes 27 can be separated from one another by walls made of insulating material be. In the illustrated embodiment, however, is also in the case of an over the electrodes 27 between the phases of the passing arc, the compressed gas extinguishing initiated. The shell 16 with the auxiliary spark gaps can also be used if necessary the auxiliary valve 13 can be assembled directly.

If there is sufficient pressure in the pressurized gas vessel 25, it acts the compressed gas in it on the piston 23 and moves it upwards. as Limitation is on the guide pin. 24 an adjustable stop 29 attached, against which the hollow piston rod rests. When the piston moves upwards the electrodes 5 the counter electrodes 3 to the adjustable distance at 29 which corresponds to the most favorable extinguishing distance. This is normal the arrangement. If z. B. as a result of the failure of the compressed gas generation system Pressure in container 25 below the value required for arc extinction drops, the spring presses the piston 23 downwards and thereby increases the rollover distance between the electrodes 3 and 5 so far that the spark gap does not respond take place. can. It is thus avoided by this device that the surge arrester responds when the gas pressure is not high enough to effectively extinguish the Bring about arrester arc.

Claims (6)

PATENT CLAIMS: i. Surge arrester with spark gap, whose Arc is extinguished by flowing compressed gas, according to patent 545: 246, thereby marked that with the compressed gas spark gap set to the most favorable extinguishing distance (3, 5) a further spark gap (9) is connected in series, the electrode removal of which is dimensioned so that the response voltage of the overall combination takes into account has the required value for the overvoltages to be diverted. 2. Surge arrester according to claim i, in which the externally supplied compressed gas by the diverter flow is controlled, characterized in that the with the compressed gas spark gap (3, 5) in-line spark gap (9) due to thermal expansion of the surrounding area Medium, gases or liquid, an auxiliary valve (i3) is actuated, which in turn controls the controls the compressed gas valve (i4) located in the compressed gas line (8). 3. Surge arrester according to claim 2, characterized in that the with the compressed gas spark gap in Spark gap (9) lying in series in a preferably gas-filled insulating sleeve (ii) is arranged, which is connected by a pipe (i2) to the auxiliary valve (r3) in such a way is that the Heating expanding gas immediately actuates the piston of the auxiliary valve (= 3) (Fig.2). q .. Surge arrester according to Claims r to 3 in a multi-phase arrangement, characterized in that the with the compressed gas spark gaps in series spark gaps (27, 28) of the individual Phases are arranged in a common housing (z6); that by warming his Air or gas content that controls the compressed gas valve (z3, 1q) common for all phases (Fig. 3). 5. surge arrester according to claim i, characterized in that at. Place of. two spark gaps only one spark gap with movable electrodes is provided, the distance of which in the idle state to the required response voltage is set and after the spark gap has responded automatically to the for the compressed gas extinguishing is reduced the most favorable value. 6. Surge arrester according to claim z to 5; characterized in that one by the pressure of the compressed gas affected movement device with the electrodes of the compressed gas spark gap in such a way is coupled that the electrode spacing with falling gas pressure over the response distance addition is increased.