Compressed gas high tension circuit breaker, requiring low operating energy

The invention relates to a compressed gas high tension circuit breaker requiring low operating energy. The circuit breaker is located in a gas tight enclosure filled with gas having high dielectric power, and comprises a fixed assembly including a main contact and an arcing contact, and a moving assembly including a main contact and an arcing contact. The moving assembly includes a chamber (21) which is delimited by two tubular elements (20, 18A) each of which slides over two tubular surfaces (7, 8) of the fixed assembly, said chamber being in communication with the zone in which the arcing contacts separate via a plurality of holes (18B).

The invention relates to a compressed gas high tension circuit breaker 
requiring low operating energy. 
BACKGROUND OF THE INVENTION 
The present invention relates, more precisely, to circuit breakers of the 
type which contain a gas having good dielectric properties, such as sulfur 
hexafluoride, at a pressure of a few atmospheres. 
Further, it relates to puffer type circuit breakers including a chamber in 
which gas is compressed when the circuit breaker openings and is directed 
towards the zone where the arcing contacts separate. Further, when 
interrupting high intensity currents (e.g. short circuits) the arc which 
is struck between the arcing contacts heats the surrounding gas and 
increases its pressure. 
An air of the present invention is to provide a circuit breaker in which 
the local pressure increase due to the arc is used to assist in displacing 
the moving parts of the circuit breaker, thereby reducing the amount of 
energy required to open the circuit breaker. 
Another aim of the invention is to provide a circuit breaker in which the 
speed at which the moving assembly moves away from the fixed assembly when 
the circuit breaker is opened increases with increasing intensity of the 
current to be interrupted. 
SUMMARY OF THE INVENTION 
The invention provides a compressed gas high tension circuit breaker 
requiring low operating energy, said circuit breaker comprising a sealed 
enclosure filled with a gas of high dielectric power, a fixed assembly 
including a main contact and an arcing contact, and a moving assembly 
including a main contact and an arcing contact, the circuit breaker 
including the improvement whereby the moving assembly further includes a 
chamber which is delimited by two tubular elements each sliding over two 
tubular surfaces of the fixed assembly, said chamber being put into 
communication with the zone in wnhich the arcing contacts separate by 
means of a plurality of holes.

MORE DETAILED DESCRIPTION 
The circuit breaker comprises an insulating envelope 1 which is cylindrical 
about an axis XX, a fixed mechanical assembly 3, and a moving mechanical 
assembly 12. The envelope is gastight and is filled with a gas having good 
dielectric properties, e.g. sulfur hexafluoroide, at a pressure of a few 
atmospheres. 
The space lying between the envelope and the mechanical assemblies is 
referenced 2. 
The fixed assembly 3 comprises a metal tube 4 serving as a fixed arcing 
contact, and terminated by a portion 4A of material which withstands the 
effects of arcing (e.g. tungsten). 
The tube has a plurality of holes such as 4B for allowing the gas to pass 
at the end of a circuit-breaking operation. 
A ring 5 is fixed to the tube 4 (or is integrally machined therewith) and 
bears contact fingers 6, thereby constituting the main fixed contact of 
the circuit breaker. The fingers 6 are protected by a discharge-preventing 
cap 7. 
There are holes such as 5A through the ring 5 in order to evacuate hot gas 
at the end of a circuit-breaking operation. 
Finally, the ring carries a thick cylinder 8 of insulating material which, 
for reasons explained below, is intended to limit the volume of gas in the 
chamber 21 situated to the righthand side thereof (as shown in the 
figures). 
A duct 8A passes through the cylinder 8 and puts the chamber 21 into 
communication with the space 2 via a non-return valve 5B through the ring 
5. This disposition is used to enable the chamber 21 to be filled when the 
moving contact is in motion, thereby avoiding a braking effect due to 
suction. As is explained below, when the pressure increases in the chamber 
21 because of the temperature rise to the arc, the valve 5B closes. 
The fixed assembly also has a piston 9 of annular section, and a portion 
rod 10 in the form of a tube having a portion of reduced thickness 10A. 
A non-return valve 9A serves to put both sides of the piston into 
communication with each other, thereby facilitating filling of the chamber 
17 located to the left of the piston in the figures when the circuit 
breaker is engaged. 
The moving assembly 12 includes two tubes 13 and 14 which are coaxial with 
the axis XX. 
The tube 13 which is the closer to the axis, has contact fingers 12 
disposed in a bell configuration to cooperate with the tube 4. 
A disk 13A is fixed to the tube 13, and together with a disk 4C fixed to 
the tube 4 serves to delimit an axial volume 25. 
Holes 13B through the tube 13 allow hot gas to escape when an arc is being 
extinguished. 
The tube 14, together with the tube 13 constitutes a cylinder of annular 
section within which the piston 9 is slidably mounted. 
This cylinder is closed at one end by a ring 15 which is provided with 
holes 15A for pressure balancing when the circuit breaker is engaged and 
disengaged. The ring 15 carries electrical contacts 15B which slide over 
the tube 10 in order to pass the electrical current. 
The tube 14 and the tube 13 are connected at the other end of the cylinder 
by a ring 16 having a nozzle 18 made of insulating material. 
The ring 16 has large holes therethrough putting the inside chamber 17 of 
the cylinder into communication with the volume 19 lying between the 
contacts 12 and the nozzle 18. 
The nozzle has a throat 18A which comes into contact with the tube 4 in 
order to close the volume 19. The holes 18B provide passages for gas to 
pass through the nozzle in a generally radial direction for reasons and 
under circumstances which are described below. Beyond the throat, the 
nozzle has an elongate portion 18C which is terminated by a flange 180 
coming into contact with the cylinder 8. 
The tube 14 has a portion 14A situated beyond the ring 16 and serving as 
the main moving contact. 
Finally, the disk 16 has a tubular portion made of insulating material and 
having an inwardly directed flange 20A at its end which comes into contact 
with the tube 7. The chamber volume lying between the nozzle 18 and the 
fingers 6 is referenced 21. 
The circuit breaker operates as follows: 
When in the closed position, electrical current passes along the tube 4, 
the ring 5, the fixed main contacts 6, the tube 14, the ring 15, the 
contacts 15B, and the tube 10. 
Interrupting a high intensity (short circuit) currents 
The moving assembly connected to an operating member (not shown) moves to 
the right (as shown in the figures). The main contacts move apart and 
current then passes solely through the arcing contacts. 
When the arcing contacts separate (FIG. 2) an arc 30 is struck therebetween 
and heats the surrounding gas whose pressure, which has already begun to 
rise by virtue of the relative displacement of the piston 9 now begins to 
rise very fast and very far. This pressure is conveyed via the holes 18B 
into the chamber 21. Since the area S2 of the chamber is greater than the 
area S1 of the cylinder 17, the resultant of the pressure forces is a 
force tending to urge the moving assembly in the direction in which it is 
moving. 
This force, and consequently the speed at which the moving assembly is 
displaced, increases with increasing intensity of the current to be 
interrupted. 
On the first zero crossing of the current, the arc is extinguished by the 
blast of gas thrust by the piston 9 through the chambers or volumes 17 and 
19. 
At the end of the circuit breaker opening process, the tube 20 leaves the 
tube 7, and the nozzle 18 leaves the cylinder 8, thereby opening the 
chamber 21 to evacuate the gas towards the volume or space 2. 
The holes 4B, 5A, and 13B also serve to provide paths for gas evacuation. 
The distances between the ends of the tubes 20 and 7 and between the ends 
of the parts 8 and 18 (in the open position of the circuit breaker as 
shown in FIG. 3) are chosen in such a manner as to ensure good dielectric 
behavior between the fixed and moving assemblies. 
However, at less than 72 kV, the tube 20 may remain in contact with the 
tube 7 at the end of a circuit-breaking operation without spoiling proper 
dielectric behavior of the circuit breaker. 
Interrupting low intensity currents (interrupting unloaded or capacitive 
currents) 
The gas compressed by the piston 9 in the volume or chamber 17 is 
sufficient to extinguish the arc.