Subject of the invention
[0001] This invention relates in particular to a SF
6 circuit-breaker which relies on a pump or puffer for forcing a blast of relatively
cool gas into the arcing region of the breaker to promote arc extinction.
Background of the invention
[0002] US-Patent 3,551,626 discloses a puffer type circuit-breaker comprising a tube shaped
fixed contact piece and a rod shaped movable contact piece representing at the same
time a single nozzle configuration.
[0003] During an opening operation an arc is established in the appearing gap, and means
for forcing a blast of arc extinguishing gas into the arc region are provided for.
Said means consist mainly of an arrangement of a fixed cylinder and a movable piston
having a cylindrical extension of insulating material.
[0004] Said extension surrounds the contact pieces during their closed position. During
a current interruption the extension surrounds the arc further condensing the gas
and directing a blast of it towards the arc. Additionally the cylinder of insulating
material prevents the arc from eroding the wall of the housing made of insulating
material. In the open position of the contact pieces the extension is removed from
the gap zone being thus established in a free gas atmosphere.
[0005] Disadvantage with the heretofore known circuit-breaker: reduced interrupting capacity
due to the application of a single-blast nozzle arrangement.
[0006] From the Federal-Republic-of-Germany-Patent 19 66 972 has become known to combine
a dual-blast nozzle arrangement with a compression cylinder in principle functioning
similarly to the cylindrical extension as described in the US-Patent 3,551,626.
[0007] Whereas the compression cylinder of said German patent is made of insulating material,
too, in a variant to this construction, according to the Federal-Republic-of-Germany-Patent
22 11 617 the compression cylinder is made of electrically-conductive material working
also as movable contact piece carrying mainly the continuous current.
[0008] In both cases the stationary nozzles consist of electrically conducting material.
[0009] Disadvantage with the heretofore known circuit-breaker: nozzles made of electrically
conductive material bring about basically at higher rated voltages an unfavorable
influence of their dielectric dimensioning on their gas flow behaviour and vice versa.
[0010] In contrary to the foregoing German patents the US-Patent 4,086,461 describes a stationary
dual-blast nozzle arrangement employing for the nozzles electrically insulating material.
[0011] Disadvantage with the heretofore known circuit-breaker:
due to the nozzles made of electrically insulating material arcing contacts are necessary
inside of both nozzles.
[0012] This complicates the construction considerably.
[0013] A movable dual-blast nozzle system whereat both nozzles are made of insulating material
discloses US-Patent 4,048,456.
[0014] A movable dual-blast nozzle arrangement with one nozzle being electrically insulating
whereas the other nozzle being electrically conductive became known from the Federal-Republic-of-Germany-Non-Prosecution-Application
28 28 773.
[0015] Common disadvantage with the heretofore known circuit-breakers:
Problem of optimizing a dual-blast nozzle arrangement due to limited space ; hazard
of hot gases escaping from the nozzle and penetrating into the surrounding space reducing
there the dielectric strength.
[0016] The proposals, so far known, dealing with the problem of increasing the pressure
of the quenching gas at a given time for compression or reversely to reduce the compression
time at a given gas pressure may be attributed to three different systems:
Systems with a single compression cylinder being engaged with a single movable compression
piston.
[0017] Such systems are described e.g. in the Federal-Republic-of-Germany-Patent 19 66 973
and Federal-Republic-of-Germany-Non-Prosecution-Application 22 45 423.
[0018] Disadvantage with the heretofore known circuit-breakers: additional gear members
being partially spring driven involve increased operating energy due to friction losses
and additional failure hazard.
[0019] Systems with a graduated single compression cylinder being engaged with an appropriate
compression piston consisting of a fixed and a movable component piston being arranged
in parallel.
[0020] An example referring to this is given in the Federal-Republic-of-Germany-Non-Prosecution-Application
23 61 687.
[0021] Disadvantage with the heretofore known circuit-breakers: low utilization of the space
being at disposal necessitates large dimensions; employment of a spring for support
of the movable piston component.
[0022] Systems employing a single compression cylinder being engaged with a fixed and a
movable compression piston arranged in series.
[0023] An appropriate example is disclosed in the Federal-Republ.- of-Germany-Patent 27
347.
[0024] Disadvantage with the heretofore known circuit-breakers : appreciable constructional
expenditure and limited compression rate.
[0025] For a reduction of the energy necessary for the actuation of the contact pieces and
compression of the quenching gas it turned out to be better to perform these two operations
not simultaneously but one after the other. This offers the further advantage of saving
operational energy by transformation of mechanical energy into pneumatical energy.
[0026] One possibility of realization offers the employment of a special gear to actuate
the compression cylinder and compression piston according to the Federal-Republic-of-Germany-Non-Prosecution-Application
29 14 033.
[0027] Disadvantage with the heretofore known circuit-breaker:
a multitude of gear members complicates the construction; need for additional operational
energy due to friction losses and acceleration of gear members;
problems to controll precisely the set in of gas compression.
Aim of the invention
[0028] The invention is aiming at a general technical improvement of the existing high-voltage
puffer type SF
6 circuit-breakers.
[0029] In a first step this will result in a higher rated voltage per single interrupting
unit at a given or even increased rated short-circuit interrupting current.
[0030] Thus the number of interrupting units per circuit-breaker pole may be appreciably
reduced - e.g. only two breaking units per 550 kV circuit-breaker pole or one unit
per 300 kV pole - rendering the circuit-breakers more reliable due to the reduced
number of components.
[0031] In a second step the gas puffer system will be made more effective avoiding at the
same time a complicated and costly gear system for the actuation of the pump.
[0032] Furthermore the breaking time will be reduced up to two cycles at 60 Hz.
[0033] High-voltage puffer type circuit-breakers of conventional design for high short-circuit
interrupting currents need still a powerful and consequently costly operating mechanism
as a result of the coincidence of the acceleration of the movable components with
the gas compression. Owing to this situation it is a third aim of the invention to
reduce appreciably the energy being necessary for the actuation of the circuit-breaker,
or reversely, to increase the short-circuit interrupting current at a given operating
energy. This will be done without complicating the operating mechanism.
Realization of the invention
[0034] The aim of this invention as indicated in the foregoing section is realized as hereafter
summerized, elucidated by figures and defined by claims.
Summary
[0035] The major problems being still imposed on SF
6 puffer type circuit-breakers as laid down under the title "Background of the invention"
are solved as follows:
In a stationary dual-blast nozzle arrangement a first nozzle is made of electrically
conductive material whereas a second nozzle is made of electrically insulating material.
In doing so the advantages of high thermodynamic efficiency and high dielectric strength
are integrated into a pressurized arcing chamber.
[0036] The contact system is splitted into two components:
The system for carrying the continuous current is arranged outside of the compression
cylinder. To make this feasible said compression cylinder of insulating material carries
a comparatively thin tube of copper.
[0037] The movable arcing contact piece is arranged inside of the dual-blast nozzle arrangement
drawing thus the arc right away at the proper spot.
[0038] All movable parts of the contact system are connected with each other mechanically
rigid and suitable for carrying electrical currents.
[0039] They are jointly operated together with the compression cylinder whereat the actuating
rods are arranged in such a way as not to impede the downstream gas flow.
[0040] To reduce the electrical field strength in the interrupting zone the front sides
of the movable contact pieces for the continuous current and arc current complement
one another to a large electrode.
[0041] For SF
6 puffer type circuit-breakers the time needed for the compression of the gas is decisive
on the total duration of the interrupting process.
[0042] Consequently emphasis has to be put on to shorten the compression time as far as
possible introducing simultaneously straightforwardness and reliability into the new
design.
[0043] This problem is solved bei substituting a conventional single acting compression
arrangement in favour of a dual acting one. Said new compression arrangement is characterized
by two compression cylinders of different diameter and material both being engaged
with two appropriate piston. The first piston is fixed whereas the second piston is
resting during the initial time interval of the interrupting process in a locked position,
said locking means being set off in the course of the travel of the second cylinder.
[0044] The first cylinder-piston arrangement which is made mainly of insulating material
represents a pressurized chamber surrounding the arc interruption zone.
[0045] The second cylinder-piston arrangement which is made of metal acts as an adjustable
gas compressor boosting additionally SF
6 gas into the arcing chamber.
[0046] A further main feature represents the pneumatical communication between the two cylinder-piston
arrangement being located outside of the permanently fixed piston, and comprising
a check valve.
[0047] The dual-acting compression system offers also the advantage that even after the
release of the gas flow through the nozzles the second cylinder piston arrangement
is still in a position to boost gas into the arcing zone increasing thus the interrupting
capacity.
[0048] A third feature of the invention represents the reduction of the energy being necessary
for the operation of high-voltage puffer type circuit-breakers. The procedure is as
follows:
In the course of a current interruption in a single gas volume or in a first gas volume,
provided the compression system consists of two separate gas volumes, the quenching
gas is compressed simultaneously with the opening stroke. However, the extent of that
first gas compression is yet small.
[0049] Not until shortly before a minimum arc length, being the precondition of a successful
current interruption, the first compression rate is increased appreciably, e.g. by
action of a second gas compression arrangement contributing to the compression of
the first gas volume.
[0050] This is achieved e.g. by longitudinal slots in the wall of the puffer cylinder. By
variation of the length of those slots the initiation of the additional gas compression
can be controlled.
[0051] During this second stage of gas compression kinetic energy of the moving components
is transformed into potential energy of the gas.
[0052] Around the end of the compression stroke the second compression piston clicks into
the wall of the appropriate compression cylinder. By means of this transient connection
of the piston with the cylinder the operating mechanism of the circuit-breaker is
relieved from the gas pressure.
[0053] Further objects and advantages will readily become apparent upon reading the following
description, given in conjunction with the drawings of embodiments.
Brief description of the several views of the drawings
[0054]
Fig. 1 shows a longitudinal sectional view of a first embodiment of a circuit-breaker
constructed in accordance with the invention. The specific feature represents the
stationary dual-blast nozzle arrangement with one nozzle made of electrically conductive
material whereas the opposite nozzle consists of electrically insulating material.
The circuit-breaker is demonstrated in three switching positions: closed, arc quenching,
open.
Fig. 2 is a view similar to that of Fig. 1 but showing the first embodiment improved
by a dual-cylinder high-performance compression system characterized by a fixed and
a movable piston. The circuit-breaker is demonstrated in the closed and open position.
Fig. 3 shows a preferred clicking system for the movable compression piston according
to Fig. 2.
Fig. 4 is a view similar to that of Fig. 2, showing the embodiment of the circuit-breaker
improved by an impuls gas compression system.
Detailed description of the preferred embodiments
[0055] Referring to Fig. 1 the description will follow the substantial functional groups
as there are:
gas compression system, gas flow system, system for carrying the continuous and short
time current, system for carrying the arc current,'dielectric system and actuating
system.
Gas compression system
[0056] The gas compression employed here is of single-acting type. It is realized in the
volume (1) made up by the compression cylinder (3),carrying at the frontside a cap
(2), and the fixed compression piston (4). Further there have a share on the walls
of the volume (1) the external surfaces of the nozzles (5,6), the pipe (7) for one
part of the down stream gas flow, the arcing contact tube (8) and the filling component
consisting of the electrically conductive member (10a) and, at the front side,of the
electrically insulating member (10b).
[0057] In an advantageous manner the compression piston (4) as well as the filler and the
insulating nozzle (6) are mounted on the pipe (9) provided for carrying the other
part of the down stream gas flow.
[0058] Between the metallic part of the filler and the compression piston a movable flat
ring (11) is serving as a valve, in connection with a spring, however, being not shown
there. Said valve closes the compression volume (1) when during an opening operation
the inside pressure exceeds the outside pressure.
[0059] During a closing operation the valve opens making thus possible a refilling of the
volume (1).
[0060] The pressure of the arc quenching gas may be controlled by the overlapping length
between the arcing contact tube (8) and the electrically conductive nozzle (5).
Gas flow system
[0061] The gas flow sets in as soon as during an opening operation the arcing contact tube
(8) separates from the inside surface of the electrically conductive nozzle (5).
[0062] Provided a voltage is applied to the terminals of the circuit-breaker an electric
arc is initiated between the two electrodes, right away inside of the nozzle space.
[0063] This represents a basical progress compared with other existing solutions mentioned
previously.
[0064] During a first time intervall after the arcing contact separation the gas flow can
make use only of the full cross-section of the electrically conductive nozzle. At
the other side the gas flow is controlled by the smaller cross-section of the arcing
contact tube being shaped like a nozzle, too.
[0065] As a result of the reduced gas flow in the case of switching small inductive currents
the arc current remains stable until shortly before its natural zero.
[0066] Switching overvoltages being proportional to the value of the instable (chopped)
current are thus limited quite naturally.
[0067] The interruption of short-circuit currents needs a longer arc length due to the increased
imput of thermal energy into the gap. In this case the reduced gas flow offers the
advantage of a reduced arc power, too, due the reduced arc cooling until to the minimum
arc length. Beyond this arc length the throat of the insulating nozzle is cleared
by the retracting arcing contact enabling its full participation in the arc quenching
process. Such an arc quenching position is illustrated in the figure.
[0068] It should be emphasized here that due to the combination of an electrically conductive
nozzle with a nozzle being electrically insulating the gap length between the nozzles
and the diameter of them can be dimensioned taking into account ounly the gas flow
conditions being not influenced by the dielectric conditions and vice versa.
[0069] Furthermore it is well known that a stationary symmetrical dual-blast nozzle arrangement
represents the most effective means for the de-ionization of the arc plasma.
[0070] The tube (8) of the movable arcing contact is connected by means of the ribs (14)
with the sliding and guiding cylinder (15) transmitting at the same time.the current
to the contact fingers (24).
[0071] From the electrically conductive nozzle (5) the gas flows through the pipe (7) into
the adjacent support pipe (
16). This pipe is connected with the end flange of the porcelain housing, however,
no more visible in the drawing.
[0072] The quenching gas escaping the electrically insulating nozzle (6) is getting first
into the pipe (9), and further, no more visible in the drawing, into the gear box.
Additionally the quenching gas can escape through longitudinal slots (18) in the pipe
(9). If necessary a screening cylinder (20) can be provided for, protecting the surface
of the porcelain housing (17) from hot gases.
Contact system for carrying the continuous current and the short time current
[0073] This contact system consists of two fixed contact pieces and a contact bridge. One
of the fixed contacts is realized by elastic contact fingers on the support (21).
[0074] The other fixed contact piece represents coincidently the down stream gas pipe (9).
[0075] The movable contact piece between the two fixed contacts pieces is made up as follows
:
On the outer surface of the compression cylinder (3) of insulating material a copper
tube (23) is shrink fitted. At the one end of the contact tube the contact fingers
are resting.
[0076] At the other end the contact tube is connested electrically with the movable contact
fingers (24) by intermediate of the structural component (19). Due to this arrangement
of the contact system outside of the compression cylinder (3) it is protected against
all sorts of influences of the arc and hot gases.
Contact system for carrying the arc current
[0077] During the separation of the contact pieces for carrying the continuous and short
time current in the course of a current interruption they are paralleled by the arc
contact system. This contact system consists of the surface of the throat of the electrically
conductive nozzle (5) and the outer surface of the movable contact tube (8). Where
necessary the transition of the current between the arc contacts can easily be still
improved by application of contact ribs (26) inside of the nozzle. The influence of
such ribs on the gas flow is small.
[0078] After building up an appropriate gas pressure in the volume (1) and commutation of
the current the arcing contacts separate. Here again the arcing contact system exhibits
the advantage that the arc drawn is immediately exposed to the gas flow preparing
its interruption.
[0079] Thus any time delay needed elsewhere for moving the arc from the outer surface of
the nozzle (5) into its throat is avoided.
[0080] From the arcing contact tube (8) the current flows through the ribs (14) to the sliding
cylinder (15). This cylinder is connected by means of other ribs fixed on its surface
with the structural component (19) providing a further current path to the contact
fingers (24) and gas pipe (9).
Dynamic electric system
[0081] Immediately after the separation of the arcing contacts the dynamic dielectric system
consists of the stationary electrically conductive nozzle (5) and the arcing contact
tube (8).
[0082] With increasing contact distance the influence of the field grading electrodes is
becoming more and more relevant.
[0083] At the side of the fixed contact pieces this is the ring electrode (28) attached
to the rim of the cylinder (25). At the side of the movable contact pieces the arcing
contact (8) is electrically screened by the ring electrode (29) being attached to
one end of the contact tube (23) on the compression cylinder (3).
[0084] With further increasing contact distance the influence of the ring electrode (29)
on the electric field is disappearing. Now the influence of the large sized electrode
represented by the metalic filler (10b) emerges up to domination.
Static dielectric system
[0085] Belonging to the open position of the circuit-breaker this system is characterized
by the electrically conductive nozzle (5) with the appropriate field grading electrode
(28) at one side of the open gap and the metallic filler (10b) at the other side.
[0086] The optimization in particular of the static dielectric system can be implemented
independently of the optimization of the gas flow system.
[0087] This feature in combination with electrodes of large surface at both sides of the
gap may be deemed as a considerable progress in the technique of stationary dual-blast
nozzle arrangements.
Actuating system
[0088] The actuating energy for the movable contact pieces and compression cylinder is transmitted
from the operating mechanism through a gearing - both, however, not shown in the figure
- by means of two rods (30) being pivotally fixed in (31).
Housing of the active parts for current interruption
[0089] The exampel given describes the interrupting chamber of an outdoor life-tank type
circuit-breaker. Accordingly the housing (17) is realized by a porcelain vessel having
at both ends connecting flanges, however,not shown here.
[0090] At the side of the fixed contact pieces on the flange is mounted a cap providing
an expansion volume for the hot gas and carrying outside the terminals for connecting
the circuit-breaker to the bus conductor. At the side of the movable contact pieces
the pocelain cylinder is connected by its flange to the gear box of the circuit-breaker
in the case of a two- or three-unit per pole type.
[0091] Referring to Fig
. 2 the single-acting gas compression system according to the Fig. 1 has now been improved
by the introduction of a dual-acting gas compression system of high performance. As
before the gas compression being decisive for the current interruption is done in
the first compression volume (1). It surrounds the dual-nozzle arrangement during
the precompression and arcing period.
[0092] In the same manner as with the embodiment according to the Fig. 1 to the compression
cylinder (3), being called here the first one, is attached a contact tube (23). However,
this contact tube now makes up additionally together with the compression cylinder
(3) a channel (32) for the gas communication between the first (1) and the second
(33) gas volume. A check valve (42) controls the gas flow through the openings (38)
being possible only in the direction from the volume (33) to the volume (1).
[0093] In the first time interval of an opening operation the movable compression piston
(35) remains catched by means of spring loaded balls and a notch round the surface
of the gas-pipe (9). An other check valve (43) prevents the gas from escaping during
an opening operation and enables the refilling of the volume (33) to be done during
a closing operation.
Run of a gas compression
[0094] The actuating rods (30) are moving the contact pieces (23) and (8) in connection
with the compression cylinders (3,34) into the opening direction. Therefrom the gas
pressure is rising in both volumes (1,33), however, with different rates of rise.
Due to its comparatively smaller height the rate of rise of the gas pressure in the
volume (33) is superior to that in the volume (1). Hence a flow of gas is forced from
volume (33) into the volume (1).
[0095] In the exampel as just being described the rate of precompression is about 1.7. Inspite
of this comparatively high compression rate the total stroke of the compression and
contact system is only 180 mm.
[0096] If necessary a further increase of the compression rate would be easily feasible
by increasing only slightly the outside diameter of the second compression cylinder
(34). At the other hand in this way at an unchanged compression rate the time needed
for it can be reduced appreciably. This again results in a very small breaking time
unsurpassed by the conventional SF
6 puffer type circuit-breakers.
[0097] Furthermore the compression system according to the invention can be easily designed
as to provide quenching gas even after the release of the gas flow into the nozzles
compensating thus the pressure drop.
[0098] This feature is of high importance for restrike free switching of capacitive currents
at very high voltages.
[0099] In the course of the opening operation a volume is appearing between the fixed piston
(4) and the cap (36) on the cylinder (34). For the ventilation of this volume holes
(39) are provided for at the end of the wall of the compression cylinder (3).
[0100] Referring now to Fig. 3, there is illustrated a favourable variant of the notching
system for the compression piston (35). Following this design the movable compression
piston is mounted on the tips of three rods (44) being distributed along the circumference
of a circle. At the other end each rod dips into a ring of elastic fingers (46) catching
a notch (47) round the rod surface.
[0101] By means of a tube (48) surrounding those fingers their elasticity can be easily
adjusted.
[0102] Thus the piston (35) remains fixed until the maximum gas pressure is reached. Then
the cap (36) takes along the piston (35) into the open position.
[0103] Compared with the embodiments of the preceding figures the gas compression sytem
according to Fig. 4 to be described now is further developed regarding its efficiency.
[0104] In the closed position of the circuit-breaker both nozzles the conductive (5) and
the insulating (6) one are suroun- ded by a compression cylinder (3) made of insulating
material. Thus the compression volume (1) is made up. It is followed by an other compression
volume (33) being surrounded by a metallic compression cylinder (34) rigidly connected
to the compression cylinder (3).
[0105] To the insulating compression cylinder (3) belongs the fixed piston (4) also consisting
at its front side of insulating material. To the metallic compression cylinder (34)
belongs the catched piston (35) made of metal, too.
[0106] The metallic cylinder (34) according to the present design elongates into a conductive
tube (23) surrounding the cylinder (3) realizing the channel (32) connecting the volumes
(1) and (33). The outer surface of the tube (23) serves in the same manner as before
as movable contact piece carrying the continuous and short time current. It corresponds
with the fixed contact pieces (22). The other component of the movable contact represented
by the cylinder (34) corresponds with the other fixed contact pieces (50).
[0107] As before the catched piston (35) is fixed on the tips of three rods (44) being a
part of the notching system (45,46, 47) as having been described already in connection
with Fig. 3.
Run of an impuls compression
[0108] In the first time interval of an opening operation being initiated by the actuating
rods (30) the quenching gas is compressed only in the volume (1).
[0109] The rate of gas compression which, however, is still moderate can be controlled easily
by the check valve (42).
[0110] Outside of the volume (1) the movable contact piece (23) separates from the fixed
contact piece (22) whereby the interrupting current commutates on to the arcing contact
pieces (5) and (8). In the volume (33) for the time being practically no gas compression
takes place because the gas can escape through the slots (51) in the wall of the cylinder
(34).
[0111] Not until after the closing of these slots by the catched piston (35) the gas compression
sets in impulsively. The compressed gas flows through the channel (32) into the volume
(1) increasing there the density of the gas further. During this second time intervall
the arc contact piece (8) separates from the electrically conductive nozzle (5) and
.an arc is drawn inside of the nozzle. This arc is cooled by the high pressure gas
flow forcing its extinction in a coming current zero.
[0112] During the arc time interval the gas pressure increases further due to the energy
imput from the arc. In case of a conventional compression system this would necessitate
increased operating energy combined with increased costs.
[0113] According to the improved compression system the catched piston (35) engages with
the compression cylinder (34) and neutralizes the forces due to the gas pressure on
the front walls of the now combined cylinders (3) and (34). The state of engagement
may be seen on the right of the longitudinal axis.
[0114] The catching system consists of a spring loaded ball resting in a ring notch.
[0115] The spring force on the balls is encreased by the gas pressure.
[0116] Synchronized with the engagement of the cylinder (34) with the piston (35) its carrying
rods (44) disengage enabling the travel of the combined components into the open position.
[0117] A variant of the impuls gas compression is illustrated on the right of the midline.
According to this design the compression cylinder (34) is not provided with slots.
In spite of that during the first time interval of an opening operation the gas compression
rate is only moderate as the gas can escape still through a ring slot established
between the gas pipe (7) and the cap of the cylinder (3).
[0118] The impuls compression sets in as soon as the cylinder cap is leaving the gas pipe
surface by moving over the surface of the nozzle (5).
[0119] The advantage of this design variant : the check valve may be dropped.
[0120] Although there have been illustrated and described specific structures, it is to
be clearly understood that the same was done merely for the purpose of further clarification
and that changes and modifications may readily be made therin by those skilled in
the art, without departing from the spirit and scope of the invention.
1. A gas-blast puffer type circuit-breaker comprising:
dual-blast nozzle arrangement, both nozzles being made of electrically conductive
material or alternatively of electrically insulating material, facing each other in
a fixed axial distance;
said dual-blast nozzles, each of them ending in a gas flow absorbing volume, being
temporarilly surrounded by a movable single compression cylinder;
separated contact pieces for carrying continuous and arc current respectively;
the improvement of said circuit-breaker characterize:
a first nozzle (5) being made of electrically conductive material, a second nozzle
(6) being made of electrically insulating material;
a movable compression cylinder (3) preferably of electrically insulating material
bearing a contact piece (23) being intended for carrying mainly continuous current;
an arcing contact piece (8) being connected mechanically rigid and suitable for carrying
electrical currents with said movable contact piece (23).
2. The invention according to claim 1, wherein
a piston (4) being fixed mainly on a gas pipe (9) next to the second nozzle (6) being
made of electrically insulating material,
said piston being made at least partially of insulating material.
3. The invention according to the specifying and characterizing sections of claim
1, the further improvement to said inventive concept characterize:
A variable first spacial unit (1) and a variable second spatial unit (33) being mechanically
connected, said spatial units having preferably the same inner diameter and preferably
different outer diameters;
said variable spatial units communicating pneumatically with each other in a controllable
manner, said pneumatical communication (32) being arranged outside of the fixed partition
(4) separating said spatial units.
4. The invention according to claim 3, wherein
said variable spatial unit (1) being established by a first compression cylinder (3),
being made completely or at least partially of electrically insulating material, being
engaged with a first piston (4) being made at least partially of insulating material;
said variable spatial unit (33) being established by a second compression cylinder
(34), being made completely or at least partially of metal, being engaged with a second
movable piston (35) of at least partially metal, and being arranged temporarilly catchable.
5. The invention according to claim 3, wherein
on said first compression cylinder (3) being attached a tube shaped electrically conductive
member (23), in the wall of said member or between said member and the outer surface
of said compression cylinder being arranged a channel like hollow space (32), connecting
the spatial units (1,33) pneumatically, in said hollow space being positioned a check
valve.
6. The invention according to claim 3, wherein
the clear distance between the cap (36) of the second compression cylinder (34) and
the second catchable piston (35) being smaller, equal or larger compared with the
overlapping length between the movable arcing contact piece (8) and the first nozzle
(5) made of electrically conductive material.
7. The invention according to the specifying and characterizing sections of claims
1 and 3, the further improvement to said inventive concept characterize:
during a first time interval of an opening operation the gas pressure in a single
volume (1) or in a dual volume (1) and (33) being limited up to a value p1,
during a second time interval of an opening operation the gas pressure in a single
volume (1) or in a dual volume (1) and (33) being raised up to a value p2,
said gas pressure P2 being equal or higher compared with the gas pressure p1.
8. The invention according to claim 7, wherein
the wall of a compression cylinder (34) being subdivided in two zones,
of said zones the one being provided with slots (51) whereas the other zone being
not provided with slots,
during an opening operation the zone provided with slots moving first over the compression
piston (35) followed by the wall zone being not provided with 'slots thus closing
the gas outlet.
9. The invention according to claim 7, wherein
the outside diameter of the electrically conductive nozzle (5) being larger compared
with the outside diameter of the adjacent gas pipe (7),
between the outer surface of said gas pipe and the opening of the compression cylinder
(3) a ring gap being established,
said ring gap being closed during an opening operation..
10. The invention according to claim 7, wherein
in the course of an opening operation a compression piston (35) being engaged in the
wall of a compression cylinder (34),
said engagement being released during a closing operation.