DE637671C - Current extinguishing chamber - Google Patents

Description

GERMAN EMPIRE

ISSUED ON
NOVEMBER 2, 1936

REICH LATE OFFICE

PATENT LETTERING

CLASS 21 c GROUP 36oi

in Berlin*)

Flow quenching chamber

Patented in the German Empire on December 22, 1934

Flow extinguishing chambers have become known in a wide variety of designs, in which the liquid flow desired to extinguish the arc is through a Differential pumping device is generated, which is automatically actuated by the arc gas pressure, is working. In all of these devices, the speed of movement of the pump piston is depending on the respective extinguishing chamber pressure, but independent within certain limits the current position and switching speed of the movable pole. This can be especially true for arcing chambers in which the flow cross-section is for the pressure fluid forms between the pole pin and the pump piston surrounding it, lead to unpleasant disturbances in the deletion process. Is z. B. with very high short-circuit power, the gas surge is very strong, this is how the piston speed is despite the arrangement of safety outlet valves in the extinguishing chamber can be greater than the pole speed and the piston will slide over the pin. This will happen all the more.

th when the clear diameter of the opening in the plunger is already a burn-off has become bigger.

The invention avoids this drawback in the known devices.

According to the invention are between the space of the differential piston and the liquid space outside of the extinguishing chamber or a plurality of control slides are arranged, which control the amount of liquid displaced from the piston chamber regulate depending on the movement of the pole pin. Is the outflow cross-section fully open, the pump piston will move quickly; with throttling of the outlet cross-section the piston movement becomes slower and the piston stops as soon as the outflow cross-section is reached is locked.

Become a series of outlet openings in the direction of piston movement in the cylinder wall the differential pump arranged and one after the other by the control slide accordingly The progressive movement of the pole pin opens, so the differential piston follows at the speed of the pole spindle and automatically closes the one from the slide exposed openings. So the piston can never make a greater way than the slider or the pole pin have moved back.

It is also possible to give the control slide an additional sliding surface, each of which closes the outflow cross-sections opened by the slide and keeps them closed, while the next outlet opening is released. In this case, the sealing surface of the differential piston on the cylinder Wall of the quenching chamber can be kept narrow as in the known designs.

*) The patent seeker stated as the inventor:

Leonhard Haag in Frankfurt a. M.

The control slides are expediently attached to a crossbar of the pole spindle, this cross-connection serving as a switching bridge © :, for the pole spindles of the individual extinguishing comb $ 3ji in the case of a multi-pole arrangement of the switch. ^: . · || λ

In the drawing, an exemplary embodiment for such an extinguishing chamber is shown. The fixed pole contact δ is attached to the upper cover of the arcing chamber α, while the pole pin c can be moved downward out of the arcing chamber. The differential piston d , which is held in its upper end position by a spring, is arranged in a circle around the pole contacts. The annular space f of the differential piston d communicates through a series of openings g with the space outside the quenching chamber. When the switch is switched on, the openings g are closed by one or more hollow slides h which are pressed against a base k by springs i. The pillars k are permanently connected to the switching bridge I for the pole pins c. If the switching bridge I moves downwards, the hollow slides h follow immediately and one after the other open the pressure equalization openings g in the cylinder wall of the quenching chamber a.

If a short circuit in the line network initiates a disconnection process, as soon as the pole pin c leaves the fixed contact b , the arc that forms in the quenching chamber causes a pressure increase that tries to push the differential piston downwards. The pipe slide h is dimensioned so long in its overlaps of the outlet openings g that it exposes the first of the openings as soon as the arc has reached a certain minimum length. Only from this moment on can the liquid content escape from the annular chamber f , so that the pressure difference between the quenching chamber space and the annular space f pushes the differential piston downwards, i.e. the piston d can lag behind the pole pin c. If the piston speed exceeds the switching speed of the pole pin c due to the pressure conditions currently prevailing in the arc chamber, the sealing surface m of the piston d will close the opening g exposed by the slide h before the slide > has opened the next outlet channel. The liquid content enclosed in the annular space f brakes the movement of the piston d and brings it to a standstill. The differential piston can only do its .Pumparbeit again when the pole pin continues to move and the slide has released a new channel g for fluid equalization. Through this positive control of the piston movement guarantee is advised that the pump piston always remains near the summit ■ jfjSs Polstiftes c and can not penetrate through the POI '■' itiit out. During the entire switching process, the extinguishing liquid will flush the arc over the tip of the pole pin at approximately the same speed until final extinction takes place when the current crosses zero.

In order to avoid excessive internal pressure in the chamber and thus destruction of the chamber, overflow valves η are attached in a known manner, which open at a certain pressure and reduce the internal pressure to the permissible level.

Claims (4)

, Claims: 1. Flow extinguishing chamber with a differential pump piston driven by the arc gas pressure, which injects a jet of liquid into the arc for the purpose of extinguishing the same, characterized in that the amount of liquid flowing out of the space (f) of the differential piston in communication with the liquid space outside the extinguishing chamber , is controlled by one or more control spools (h) depending on the movement of the pole pin (c). 2. Flow extinguishing chamber according to claim i, characterized in that the annular space (f) of the differential pumping device is connected to the space outside the extinguishing chamber through a series of outflow openings (g) , which are opened one after the other by a control slide (h) will. 3: flow extinguishing chamber according to claim ι and 2, characterized in that the movable pole spindle (c) carries a crossbar (I) which connects the different pole spindles with each other in a multi-pole arrangement and the control slide (h) for the individual outlets (g) of the Pressure chamber (/ ") of the pumping device moves. 4. flow extinguishing chamber according to claim ι to 3, characterized in that the control slide (h) following differential pump piston (d) or the control slide (h) itself has an additional control surface which each closes the outflow cross-sections (g) opened by the control slide and keeps it closed. 1 sheet of drawings