DE629739C - Device for extinguishing AC interruption arcs - Google Patents

Description

Device for extinguishing alternating current interruption arcs The subject of the main patent is a device for extinguishing alternating current interruption arcs in a narrow insulating envelope opening into expansion spaces with the aid of a liquid, which under an external pressure during the extinguishing process the extinguishing room to a, or several places separate from the expansion mouths via buffers, which as Liquid reservoirs act and are connected in the vicinity of the extinguishing room, is supplied in such a way that new ones from the envelope simultaneously with the steam expansion Liquid is pressed into this.

The invention consists in that acting as a fluid reservoir Buffer is provided with a preload so that it is only at a certain minimum pressure appeals to. The liquid reservoir with pre-tension limits the liquid mass during the critical extinguishing time, i.e. in a fraction of a hundredth of a second, has to be accelerated, to a small amount, and at the same time it keeps it Amount of liquid ready in the immediate vicinity of the extinguishing room. He loads himself during the rising current half-wave of the alternating current arc only with the required amount of liquid and presses it in the vicinity of the current zero passage into the extinguishing room with the required acceleration. The one for the right one Effect of the arc extinguishing device required acceleration energy the liquid is thus brought to a minimum value that the whole There is liquid in the storage tank located in the immediate vicinity of the extinguishing room, therefore one can with a moderate external pressure the condition that during the critical Time to extinguish the uride-expanding gases and vapors flowing out of the envelope new liquid are replaced, meet to a particularly perfect degree.

By giving the liquid reservoir a corresponding pressure characteristic and the feed pressure and the preload of the - accumulator accordingly chooses, one can achieve that the fluid reservoir is just with the one Volume of liquid charges, which is required to the extinguishing space during the low-current pause of the AC arc to fill with liquid. In this case the device operates with the smallest inertial delay compared to the very rapid pulsations of the alternating current arc.

So that the pressure during the current maximum of the alternating current does not superfluous assumes a high value, it is advantageous to use the fluid reservoir add a flat pressure characteristic ..._ go, - # - d @ h: - one in which the pressure increases with the liquid uptake of the reservoir, only slightly above the pre-tensioning. In the interests of small inertia of the device, it is also expedient to reduce the 'storage volume to be accommodated in the immediate vicinity of the extinguishing room. Preferably one gives So the memory one in relation to the inflow cross-section of the liquid in the Extinguishing space large cross-sectional area with a small stroke, for example in that it is arranged around the extinguishing room.

Exemplary embodiments of the invention are shown in the drawing.

In Fig. I io is an insulating body enclosing the quenching space. Of the Arc quenching space itself has the shape of a narrow channel ii through which the movable Switching pin 12 is passed and the annular ribs 13, 1q., 15, which are built into the cavity of the insulating body io, is delimited in such a way, that only relatively narrow annular inflow slots 16, 17, 18, i9 for the Liquid remain free in the duct wall. Is connected to the extinguishing room a supply line 2o for the extinguishing liquid and a storage space 21. In the Storage space moves a piston 22, which by a spring a3, which the bias Po owns, is pressed against stops 2q., 25. The piston and spring should be as close as possible have low intrinsic inertia and the storage space behind the piston should by these must be sealed. 26 is the fixed contact of the switch. Of the Current is' fed to your switch piece 26 and from the switch pin 12 by means of a sliding contact 27 removed.

In Fig. I, the switch is in the closed state .darstellung, in Fig. 2. and 3 during the interruption process, Lind is in FIG. 2 shows the arc current in the current maximum, while in FIG. 3 it is the current zero crossing approaching.

On, a trigger command, e.g. B. the response of an overcurrent relay, a compressive force is initially triggered, which acts on the liquid in a the line 2o subsequent feed device, which is not in the drawing is shown; acts or a shut-off device in the line 2o opened, whereby Liquid in the line 2o is accelerated towards the extinguishing channel. In Fig. i is denoted by 28 -the foremost part of this liquid; those with speed v in the space surrounding the extinguishing channel I 1, which is enclosed by the capsule io will arrive. The liquid must have already filled the extinguishing channel before the; ". switching pin passes through this and 'thereby pulls the arc through it. As the liquid flows through the narrow slits between the switching pin and the wall of the Extinguishing channel i i can only flow out slowly, it is jammed. Here sits down converts the velocity energy into pressure energy. This dynamic pressure can initially only up to the level of the preload Po with which the piston 22 is loaded. If it rises beyond this, the piston 22 is pressed into the storage space 2i, -%. by means of the pressure only according to the pressure characteristics of the accumulator can enlarge. The spring 23 has a flat characteristic, so that the pressure finitely with the piston stroke rises only slightly above the preload Po.

In Figure 2, the switching pin has the arc through the extinguishing channel i i pulled through and the arc is just at the current maximum, fills so the channel i z almost completely off. Only a small amount of liquid can therefore pass through the slots 16 to i9 exit into the extinguishing channel ii, so that the liquid in the essentially in the direction of the arrow with the speed v1, which is less than v, which flows into the storage space. The liquid in front of the storage space is under the pressure P, which is slightly greater than Po.

You can see it by dimensioning the storage device .in the hand to prescribe the pressure in front of the extinguishing channel ii, whereby it must be observed, that the magnitude of the external pressure under which the liquid is placed in the supply line must be kept under a certain limit, which is determined by the bias of the Memory and the inertia of the liquid mass to the memory depends. -A A moment later the switch pin is in the position shown in FIG. 3 and the arc current is close to the current zero crossing. Consequently the arc has been severely constricted in the extinguishing channel i i. It can now in a short time Time liquid enter the extinguishing channel through the annular slots 16 to 19, since the counter pressure of the arc that prevented your penetration of the liquid, drops sharply instantly. It is essential that the. Pressing out the gas content out of the extinguishing channel through the clamping effect of the pressure fluid that is immediately penetrating is accelerated, because the clamp pressure of the liquid holds through the hit Measures so that .a strong expansion pressure gradient for the gas between the Middle of the extinguishing channel and its mouths into the expansion areas via the low-current Pause persists.

The direction of flow of the liquid during the low-current pause is essentially that illustrated in FIG. 3 by the direction of the arrow. It leads from the storage space 21 to the extinguishing channel i i. The flow velocity is denoted by Av. The speed Av is very considerable, since the mass to be accelerated in (FIGS. 2 and 3) is only small. It is expressed mathematically as a function of the storage pressure P and the liquid mass m to be accelerated as From this it can be seen that with a high mean value of the storage pressure P and small masses, a high Av and thus an almost instantaneous follow-up of the liquid behind the shrinking arc can be achieved. If the liquid now follows without delay into the extinguishing channel ii and in this way the gas expanding from the vicinity of the arc column in the axial direction from the mouths of the extinguishing channel is replaced by liquid and wet steam, then in the current zero passage at the arc column, which has shrunk to a thread-thin channel , which is clasped by the hydraulic fluid, generates such a high temperature gradient that the arc is no longer re-ignited after the current has passed through zero.

In Fig. 4, the time course of the pressure fluctuations in - the area around the extinguishing channel i i in front of the storage space is shown roughly schematically. I is the curve of the arc current, Ot is the time span in the area of the current zero passage, during which the liquid from the storage space in the extinguishing channel is pressed. All the rest of the time t1 of the current half-wave the memory is charging. During charging, the pressure increases from the bias Po to the final voltage P, and then drops back to Po.

In Fig. 5, another embodiment of the invention is shown. 30 is the extinguishing device, consisting of an insulating housing which contains the extinguishing channel 3 i and a storage space 32 which extends in a ring around the axis of the extinguishing channel. The extinguishing channel 3 1 is delimited by the built-in annular ribs 33 to 35. 36 is a slightly movable piston of ring shape in the storage space 32. 38 is the fixed switching piece, 39 the movable switching pin, -4o the sliding contact from which the current is drawn. 41 is the fluid supply line, 42 is a fluid cylinder in which the fluid pressure is generated by pressing down a piston 43. 4.4 is a with gas, e.g. B. ordinary air, filled cylinder into which the sealing piston 45 slides. The pistons 43 and 45 are pressurized by forces P and P1, which are triggered when the switch is triggered. The cylinder 44 is connected by a gas line 47 to the storage space 32 of the extinguishing device, so that this storage space below the piston 36 is filled with compressed gas.

When triggered, the pressure P1 pushes the liquid into the cylinder 42 and the line 4i under a surface pressure p1 and the air in the Cylinder 44 and the storage space 32 by the force P under a surface pressure p set. p1 is only slightly larger than p and the value of p1 in the space is immediate in front of the extinguishing channel 3i decreases to the extent that the flow velocity increases. In the drawing, the device is during the interruption process shown at the moment when the arc current has its maximum value, so the greatest stagnation of the liquid flow occurs after the extinguishing channel. Of the The pressure in your liquid space in front of the extinguishing channel then has almost the full value p1. The piston 36 is therefore due to the pressure difference p1 to p in the storage space 32 pressed in. and this absorbs the inflowing liquid. In the low power Pause, the static pressure in front of the piston 36 is converted into flow energy, so that p1 drops below p, whereby the piston 36 moves upwards and the releases liquid absorbed by the storage space into the extinguishing space. As when pushing in of the piston 36 in the storage space 32 the reduction in volume of the entire air or Gas volume in the cylinder 44, in the line 47 and in the storage space 32 relatively is low, the pressure increases only a little.

The flat pressure characteristic of the buffer has the advantage that the Arc is not unnecessarily placed under high pressure during the current half-wave will. The external pressure p need only be slightly higher than the preload p of memory.

Instead of pistons in the storage spaces, flexible ones can also be used membrane Or elastic surfaces made of rubber or the like. Use their Spring force has the desired characteristics.

The external supply pressure for the liquid can be controlled by a release force accumulator of the switch, e.g. B. with the help of a pump piston, generated or thereby, that the liquid in the supply line is put under gas pressure.

The liquid can be a semiconducting, e.g. B. water, use so you are not bound to insulating liquid.

Claims (1)

PATENT CLAIMS: i. Device for extinguishing alternating current interruption arcs in a narrow insulating envelope opening into expansion spaces with the aid of a liquid, which under an external pressure during the extinguishing process the extinguishing chamber on a or several places separate from the expansion mouths via buffers, which as Liquid reservoirs act and are connected in the vicinity of the extinguishing room, is supplied in such a way that new ones from the envelope simultaneously with the steam expansion Liquid is pressed into this, according to patent 626 72o, characterized that the buffer acting as a liquid reservoir is provided with a bias is so that it only responds to a certain minimum pressure. z. Facility according to claim i, characterized in that buffers of such pressure characteristic are provided that the buffer pressure with the liquid uptake of the buffer space increases only slightly above the preload. 3. Device according to claim i, characterized characterized in that resilient surfaces of small intrinsic inertia in the buffer space are arranged, behind which there is a liquid-free space, which they seal. q .. Device according to claim 2, characterized in that the spring force of the Buffer is expressed by a gas cushion contained in the buffer space, which is placed under a pressure which is only slightly lower than the pressure with which the liquid is supplied from the outside. 5. device 'according to claim i, characterized characterized in that the liquid buffer is one in relation to the inflow cross-section the liquid in the extinguishing chamber has a large cross-sectional area. 6. Set up after Claim 5, characterized in that one or more liquid buffers are ring are arranged around the extinguishing chamber.