Background
[0001] The invention is related to the field of medium and high voltage technologies and
concerns a self blast circuit breaker or a puffer circuit breaker according to the
independent claim, particularly for a use as power switch in power distribution systems.
Prior art
[0002] Such self blast circuit breakers, puffer circuit breakers or gas blast circuit breakers
are particularly used in high voltage switching technologies for electric current
interruption. When disconnecting two contacts, an electric arc develops between the
contacts. It is a task of said circuit breakers to quench the arc. This is done in
such a way that a gas is blown into the arc in order to extinguish it. The gas usually
used for this task is typically SF
6 (sulphur hexafluoride) because of its excellent quenching characteristics. It also
has very good dielectric properties.
[0003] A widespread method of suppressing the arc will be broadly explained in the following,
however without elaborating on all components of a circuit breaker.
[0004] The circuit breaker comprises a heating volume and an arc volume connected to one
another by a heating channel. Both volumes are filled with the gas. The arc volume
designates the space around the two contacts. As soon as the contacts are separated,
an arc develops between them and starts heating up the gas in the arc volume. Because
of the expansion of the gas volume caused by the heating up, a gas pressure difference
between the arc volume and the heating volume occurs. A second cause for the pressure
rise in the arc volume is an ablation of Teflon® from the surface of a nozzle due
to electric arc radiation. The gas starts to flow from the arc volume through the
heating channel into the heating volume, where it mixes with the "cold" gas stored
therein and causes a pressure rise inside said heating volume. Particularly at the
zero-crossing of the current, the pressure in the heating volume has to be higher
than the pressure in the arc volume. The mixed, cooled gas flows from the heating
volume back into the arc volume and quenches the arc.
[0005] It is an aim of self blast circuit breaker embodiments to quench the arc at the next
possible zero crossing of the current in order to minimize erosions of the contacts
and to limit the energy input into the circuit breaker. Amongst others, it is important
that the gas temperature is low, when the gas flows back from the heating volume into
the arc volume, in order to extinguish the electric arc efficiently. In ordinary circuit
breakers it has been observed that the flow of hot gas has a substantially toroidal
form inside the heating volume.
[0006] The patent
CH 662 443 A5 or equivalent
US 4 559 425 discloses a circuit breaker with a heating volume and an arc volume which are connected
by a gas guiding device which comprises at least three channels arranged in different
azimuthal positions around the axis. The channels have radial sections entering the
arc volume. This embodiment acts as a whirl breaker.
Description of the invention
[0007] It is an objective of the present invention to provide a self blast circuit breaker
or a puffer circuit breaker with enhanced mixing of the hot gas with cold gas in the
heating volume.
[0008] This is achieved according to the invention by providing a self blast circuit breaker
or a puffer circuit breaker according to the independent claim.
[0009] According to the independent claim, a self blast circuit breaker or a puffer circuit
breaker is provided, which has at least a first and a second contact for coupling
and decoupling an electric circuit, which are movable relatively to one another in
a parallel direction to a longitudinal axis of the circuit breaker. The contacts are
meeting each other in an arc volume inside of which an electric arc between the first
and the second contact can develop as soon as the first and the second contact are
separated. The circuit breaker according to the invention comprises an insulating
nozzle, a heating volume and a heating channelThe heating channel connects the arc
volume with the heating volume, which both are filled with an insulating gas, preferably
SF
6. The heating channel comprises at least one gas guide surface having a first and
a second end section. The first end section guides gas into said arc volume. The second
end section guides gas into the heating volume. The first end section is guiding gas
into said arc volume and has first means for guiding a gas flow into the arc volume
without an azimuthal component with respect to said longitudinal axis. The second
end section is guiding gas into said heating volume and has second means for generating
an azimuthal, i.e. tangential, component with respect to the longitudinal axis in
a gas flow entering the heating volume. In other words, the second end section or
its second means, respectively provide a swirling flow of gas into the heating chamber
for enhanced hot-cold gas mixing in the heating chamber, whereas the first end section
or its first means, respectively, provide quenching gas directly towards the longitudinal
axis of the circuit breaker for highly efficient arc extinction, with minimal gas
rotation inside the arc volume or around the arc.
[0010] The advantage of the circuit breaker according to the invention, particularly of
the specific design of the end sections, is on one hand that the hot gas develops
a flow pattern with azimuthal momentum within the heating volume, thus enhancing the
gas mixing therein, and on the other hand that the mixed gas flows onto the arc in
a more focused way and without azimuthal momentum when flowing back into the arc volume,
thus quenching the arc more efficiently.
[0011] In embodiments, the first means comprise a shape and/or arrangement and/or element
of the first end section, that have no azimuthal gas-flow-guiding component with respect
to said longitudinal axis. In particular, the first end section can be oriented radially
with respect to the longitudinal axis.
[0012] In other embodiments, the second means comprise an at least partially azimuthal shape
and/or arrangement and/or element of the second end section. In particular, the second
end section can be oriented at least partially transversely with respect to the longitudinal
axis. The term azimuthal (or transversal) shall mean gas-flow-guidance with net azimuthal
(or net transversal) orientation, i.e. shall include local and/or temporal deviations
from azimuthal (or transversal) orientation, as long as an overall at least partial
azimuthal (or overall at least partial transversal) gas flow results.
[0013] In further embodiments, the insulating nozzle and the heating volume may be arranged
concentrically to the longitudinal axis. In particular, the heating volume can be
arranged beyond an end face of the insulating nozzle around the first contact.
[0014] In an embodiment, the azimuthal component introduced by the second end section(s)
in the gas flow entering the heating volume can result in a full rotation of gas in
the heating volume, which full rotating gas flow may in addition be broken up into
smaller turbulences, e. g. by additional structural element(s) arranged inside the
heating volume, preferably on a wall opposing the entrance side of the heating channel.
Short description of the drawings
[0015] Further embodiments, advantages and applications of the invention result from the
dependent claims and from the now following description by the figures. It is shown
in:
Fig. 1 in section 1a of the figure a perspective view of an embodiment of an insulating
nozzle and in section 1b the embodiment in a top perspective view;
Fig. 2 in section 2a of the figure a perspective view of an auxiliary nozzle used
in an embodiment of the invention and in section 1b the auxiliary nozzle in an unfolded
view;
Fig. 3 an exemplary schematic view of another embodiment of the insulating nozzle
within a coordinate system;
Fig. 4 a section of a part of a self blast circuit breaker;
Fig. 5 in sections 5a - 5d four embodiments of a combination of an insulating and
an auxiliary nozzle; and
Fig. 6 in sections 6a - 6b two further embodiments of such combination.
[0016] The reference numerals used in the figures are summarized in a list. Elements which
are not necessary for the understanding of the invention may partly be not shown.
The explained embodiments are exemplary for the subject of the invention and have
no limiting effect; the invention may be executed in different ways within the scope
of the claims.
Ways of carrying out the invention
[0017] First, individual components which are relevant for the invention is explained. Subsequently,
a short description of geometrical aspects is given, an exemplary embodiment of a
part of a self blast circuit breaker comprising the already mentioned components is
described along with the effect of the components for solving the objective of the
invention, and finally a number of embodiments of the components are shown.
[0018] Fig. 1 shows in section 1a of the figure a perspective view of an embodiment of an
insulating nozzle 1. The longitudinal axis z is identical to a longitudinal axis of
the self blast circuit breaker. The insulating nozzle is known and has the task of
enhancing the arc extinction by channelling the gas and increasing the gas pressure
in the vicinity of the arc. As can be seen, the insulating nozzle 1 is arranged concentrically
around the longitudinal axis. In this embodiment, it has a narrow part 2 and a wide
section 3, connected by a "bottom" part 3f. It is noted that the bottom part 3f is
seen as part of an inner wall 3a of the insulating nozzle 1 and is not counted as
a gas guide surface in the context of this invention as it substantially has the same
purpose as the inner wall 3a and is therefore known. The notional difference is used
here only for explanation purposes. Evidently, other shapes of the insulating nozzle
1 are possible. Within the circuit breaker, which is not shown here for reasons of
clarity, the insulating nozzle 1 is arranged in such a way that its end face 3d faces
a heating volume which is not shown here. An arc volume, also not seen here, is located
in a transition area between the narrow part 2 and the wide section 3 of the insulating
nozzle 1, on the inside of the same.
[0019] The already mentioned gas guide surface is arranged at an inner wall 3a of the insulating
nozzle 1. Fig. 1a depicts an example of an arrangement with three gas guiding channels
3b, which are formed as grooves in the inner wall 3a of the insulating nozzle 1. Evidently,
the grooves 3b may have other shapes than in the shown embodiment. Each of the gas
guiding channels 3b comprises two gas guide surfaces 3c, formed by walls of the grooves
3b. In Fig. 1a only second end sections 12b (see Fig. 1b) of the grooves 3b are shown,
first end sections 12a are not visible. They are shown in Fig. 1b and will be explained
in the following.
[0020] In section 1b of Fig. 1, the insulating nozzle 1 of Fig. 1a is shown in a top perspective
view from the z direction. However, here it comprises eight gas guiding channels or
grooves 3b. In Fig. 1b, an embodiment of the insulating nozzle 1 is shown, which has
the grooves 3b formed by the gas guide surfaces 3c arranged concentrically along the
entire inner wall 3a of the insulating nozzle 1. This arrangement advantageously increases
the gas guiding effect of the insulating nozzle.
[0021] From this perspective, the first end sections 12a of the gas guide surfaces 3c are
also visible and indicated for one groove 3b as the inner, small dashed area. The
outer dashed area shows the second end section 12b of that groove 3b. It is noted
that the shown size of the first and the second end sections 12a, 12b of the grooves
3b are not a limiting factor for the present invention. For example the groove 3b
may be seen as formed by the first and the second end sections 12a, 12b only; the
only restriction is that the first end section 12a is oriented radially to the longitudinal
axis z and the second end section 12b is transversal to (i.e. has at least a transversal
component to) the longitudinal axis Z. This applies for the embodiments explained
in the following. Furthermore, the width of the groove can be substantially constant,
while Fig. 1b depicts the grooves 3b as tapering towards the middle, i.e. towards
the longitudinal axis z. This is shown in this way because the grooves extend away
from the viewer.
[0022] As broadly explained above, the gas may travel along the heating channel in both
directions; from the heating volume into the arc volume and vice versa. Thus, it also
travels in said both directions inside the grooves 3b formed by the gas guide surfaces
3c. The shape of the grooves 3b influences the flow of the gas, especially the angle
at which the gas leaves the grooves 3b into either the heating volume 8 or arcing
volume 9. The arrow B shows the flow direction of gas entering the arc volume the
position of which is here indicated by the reference number 9. In this example, it
indicates the direction of the exiting gas in case the grooves 3b extend along the
inner wall 3a of the insulating nozzle 1 only, however, they may also extend into
the bottom part 3f, as indicated by the dashed lines 3g. It is also possible to provide
grooves 3b only in the bottom part 3f. Reversely, the arrow A shows the gas travelling
direction when the gas exits from the groove 3b into the heating volume 8. As can
be seen from the direction of the arrow A, the flow has an azimuthal component, thus
a component which is tangential to the outline or inner mantle surface of the wide
section 3. The geometrical arrangement of the gas guide surface and the azimuthal
component is explained in further detail in Fig. 3.
[0023] In another embodiment of the insulating nozzle 1, which is not shown in Fig. 1, at
least one gas guide surface 3c may be formed by a fin, instead of the groove 3b mentioned
above. The fin may either be part of the inner wall 3a or it may be attached to it.
The fin may be formed such that its gas guide surfaces have a substantially same shape
as the gas guide surfaces 3c of the groove 3b. The use of fins will be explained next
in the context of Fig. 2 within the scope of a further embodiment of the invention.
[0024] The insulating nozzle 1 in either embodiment may have one gas guide surface 3c or
multiple gas guide surfaces 3c arranged at its inner wall 3a. Furthermore, not only
the first and the second end sections 12a, 12b are formed as a groove 3b or as a fin,
but the entire gas guide surface may be formed in the same way as its end sections
12a, 12b as well. Still further, a combination of fins and grooves is also conceivable
as an arrangement along the inner wall 3a of the insulating nozzle 1.
[0025] Fig. 2 shows in its section 2a a perspective view of an auxiliary nozzle 5. The auxiliary
nozzle 5 is arranged concentrically around the longitudinal axis z between a first
contact of the circuit breaker and the insulating nozzle 1, both not being shown here
for reasons of clarity. In this further embodiment, the auxiliary nozzle 5 also comprises
at least a gas guide surface 4a, which is arranged at an outer wall 6 of the auxiliary
nozzle 5. Multiple gas guide surfaces may be arranged at the outer wall 6 of the auxiliary
nozzle 5, as it is the case in the example of Fig. 2, where four fins 4 are arranged
along said outer wall 6, thus yielding a total of eight gas guide surfaces 4a. A front
face 4c of the auxiliary nozzle 5 substantially faces the aforementioned arc volume
9, which may be located in the area in front of the inner circle 4d which indicates
the beginning of an inner wall of the auxiliary nozzle 5. An end face 4b of the auxiliary
nozzle 5 faces the heating volume 8.
[0026] An overview of an embodiment of a self blast circuit breaker with an insulating nozzle
1 and an auxiliary nozzle 5 is explained in the context of Fig. 4. This will further
clarify the arrangement of both nozzles 1, 5 and of further elements of the circuit
breaker relatively to one another.
[0027] In Fig. 2, each fin 4 is divided into three parts: a front head part 4f located on
the front face 4c, an elongated part 4e located on the outer wall 6 and a non-radial
part 4g located on the outer wall 6 as well. Analogously to Fig. 1b, a first end section
part 12a and a second end section part 12b of the gas guide surfaces of the fin 4
are shown by the dashed surfaces on the fin 4. The fins 4 are used for the same purposes
as the grooves 3b of Fig. 1. The shape of the fins 4 influence the flow of the gas,
especially the angle at which the gas is guided by the fins 4 into the arc volume
9 or into the heating volume 8 respectively. The arrow B shows the flow direction
of gas entering the arc volume 9. The arrow A shows the gas travelling direction when
the gas flows into the heating volume 8 deflected by the second end sections 12b.
As can be seen from the direction of the arrow A, the flow direction also has an azimuthal
component, thus a component which is tangential to the outline or outer mantle surface
of the outer wall 6 of the auxiliary nozzle 5. The geometrical arrangement of the
gas guide surface 4a is explained in further detail in the context of Fig. 3.
[0028] Section 2b of Fig. 2 shows the auxiliary nozzle 5 in an unwound view. The dashed
arrows between section 2a and section 2b of Fig. 2 denote corresponding points of
the two views. Dashed arrow 7a shows the correspondence of an edge point formed by
the front head part 4f and the elongated part 4e. Dashed arrow 7b shows the edge of
the outer wall 6 and the front face 4c of the auxiliary nozzle 5. Dashed arrow 7c
shows the corresponding edge between the elongated part 4e and the oblique part 4g
of the fin 4. Dashed arrow 7d shows the edge of the oblique part 4g, in particular
transverse part 4g, of the fin 4. Furthermore Fig. 2b shows the flow directions A
and B of the gas in case the gas is flowing into the heating volume 8 or into the
arc volume 9, respectively. These flow directions A and B are oblique, in particular
transverse or orthogonal, to one another.
[0029] Analogously to the insulating main nozzle 1, the gas guide surfaces 4a of the fins
4 of the auxiliary nozzle 5 may be formed as grooves 3b in the outer wall 6 and may
have substantially the same shape as the fins 4 of the current example of Fig. 2.
Furthermore, only the first and the second end sections 12a, 12b may be formed as
a fin 4 or a groove 3b, contrary to this example, in which the entire gas guide surface
is formed as a fin 4. Still furthermore, a combination of fins 4 and grooves 3b is
also possible as an arrangement along the outer wall 6 of the auxiliary nozzle 5.
[0030] Fig. 3 shows a simplified view of the main nozzle 1 in another embodiment comprising
an exemplary fin 4 instead of the grooves 3b of Fig. 1. In Fig. 3 the geometrical
arrangement of the fin 4 is explained in more detail. Of course, the arrangement is
also applicable in case grooves 3b are used instead of the fin 4. In the context of
this figure, also the notion of azimuthal component introduced above will further
be explained.
[0031] Only the wide part 3 of the insulating or main nozzle 1 is shown in Fig. 3. The inside
surface of the cylinder shown corresponds to the inner wall 3a of the insulating nozzle
1 of Fig. 1. A cylindrical coordinate system is used for the description of the arrangement
of the fin 4. The cylindrical coordinate system has its origin O, a longitudinal axis
z which is identical to the longitudinal axis of the self blast circuit breaker, radial
axis ρ and an angle ϕ between the radial axis ρ and a vector ω pointing to an arbitrary
point P. Thus, each point P is described by P(p, ϕ, z). As can be seen from the figure,
a first portion 14a of the fin 4 runs in z-direction at a constant angle ϕ, which
is also called azimuth angle, whereas a second portion 14b of the fin 4 also runs
in the z-direction, however the angles ϕ varies as a function of z for each point
or longitudinal section of the fin 4. Again, the first and the second end sections
12a, 12b are shown as dashed surfaces, their sizes being exemplary only. It is also
possible to see the first end section as corresponding to the first portion 14a and
the second end section 12b as corresponding to the second portion 14b. A front part
4f, analoguous to the front part 4f of Fig. 2, is also shown in order to clarify its
location in the coordinate system. The front part 4f extends into the bottom part
3f of the insulating nozzle 1, as described as an option above (Fig. 1b). Both cases
may be seen as a radial extension of fins 4 or grooves 3b.
[0032] As mentioned, the first end section 12a being "arranged radially" may also include
the fact that the gas guide surfaces of the first end section 12a are "arranged parallel"
to the longitudinal axis z of the circuit breaker. In contrast, the second end section
12b is "arranged transversally" to the longitudinal axis z. The meaning of the terms
"arranged parallel" and "arranged transversally" is defined as follows:
- A gas guide surface is "arranged parallel" to longitudinal axis z if, for substantially
each point of said gas guide surface, the local tangential plane of said surface at
said point is parallel to longitudinal axis z.
- A gas guide surface is "arranged transversally" to longitudinal axis z if, for substantially
each point of said surface, the local tangential plane of said surface at said point
is oblique ot transversal to longitudinal axis z, i.e. longitudinal axis z and the
local tangential plane intersect (i.e. intersect one another under an arbitrary non-vanishing
angle).
[0033] This definition holds for flat as well as for non-flat sections of the gas guide
surfaces 3c or 4a. For a flat section, the tangential plane is the same for all points
on the section and coincides with the surface itself. For non-flat sections, each
point has its own tangential plane.
[0034] The above definition is based on the assumption of geometrically perfect surfaces.
In a real embodiment, where surfaces may have microscopic defects and suffer from
machining tolerances, the above definitions may not hold for each and every point
on the surface, but at least for a majority of the points.
[0035] The gas guide surfaces may also be concave or convex seen from the point of view
of Fig. 3. The tangential planes satisfy the above criteria for this kind of surfaces
as well.
[0036] In the above embodiments, the gas guide surfaces are perpendicular to the inner wall,
whereas in another embodiment they are oblique to it, in other words non-radial.
[0037] Fig. 4 shows a section of a self blast circuit breaker 10. A first and a second contact
11a, 11b are arranged substantially parallel to the longitudinal axis z. At least
one of the contacts 11a, 11b is movable relative to the other contact 11b, 11a, and
may touch that contact. This arrangement is known and will not be described here in
more detail. When the contacts 11a, 11b are separated, an electric arc 11c may develop
between the contacts 11a, 11b in the arc volume 9.
[0038] An insulating (main) nozzle 1 as the one shown in Fig. 1 is arranged concentrically
around the contacts 11a, 11b, wherein, in this exemplary embodiment, the narrow part
2 is arranged around the second contact 11b and the wide part 3 of the insulating
nozzle 1 is arranged substantially around the first contact 11a and the arc volume
9. The inner wall 3a is facing the outer wall 6 of the auxiliary nozzle 5, which is
arranged around the first contact 11a and which protrudes into the arc volume 9. The
said heating channel 16 is formed between said walls 3a and 6 of the two nozzles 1
and 5. The auxiliary nozzle 5 differs from the auxiliary nozzle 5 of Fig. 2 only insofar,
as it has an additional segment 13 pointing towards the longitudinal axis Z. The explanations
related to Fig. 2 apply here as well; therefore the numeral of the auxiliary nozzle
5 has been chosen the same. The additional segment has an outer wall 6a substantially
facing the bottom part 3f of the insulating nozzle 1. This arrangement extends the
heating channel "around the corner" and can be advantageous, because it faces the
electric arc 11c substantially perpendicularly. This is explained later in the context
of the gas flow pattern. In this example, the auxiliary nozzle 5 is attached to the
first contact 11a, it may however be attached in a different way, according to embodiments
of the prior art. Fins 4 are attached to or are part of the inner wall 3a of the insulating
nozzle 1 and the outer wall 6 of the auxiliary nozzle 5, respectively. By comparing
the front head part 4f of the fin 4 of Fig. 2 with the fin part arranged at the additional
segment of the fin 4 of Fig. 4, it can be seen that their orientation and shape are
analogous.
[0039] The end face 3d of the insulating nozzle 1 faces the heating volume 8, which can
be chosen much larger than the arc volume 9, as known by the skilled person. Two arrows
A illustrate the inflow of gas into the heating volume 8 and the arrow B shows the
inflow of gas into the arc volume 9. It is noted that each inflow takes place in a
different phase of the arc quenching process, as known from the prior art. The gas
flow and its relation to the quenching of the arc will now be explained in more detail.
[0040] Among others, the efficiency of quenching the arc 11c depends on the temperature
of the gas, namely the lower the temperature the more effective the quenching. Thus,
as mentioned above, it is desirable to be able to cool down the gas as much as possible.
This operation is done in the heating volume 8, where cold gas is mixed with incoming
gas, which is hotter because it has already been heated up by the forming arc 11c.
In present solutions, the gas flow is only channelled by the inner wall 3a and the
outer wall 6. It flows in a substantially perpendicular way into the heating volume
8 where it mixes with the cool gas by forming, as has been observed previously, a
toroidal swirl without an azimuthal component inside the heating volume 8. However,
by using the gas guide surfaces of the present invention, with their second end sections
12b being transversal to the longitudinal axis z, a part of the gas receives a third
directional component in substantially azimuthal direction. The result is an additional
azimuthal flow inside of the heating volume 8, which speeds up the gas mixing process.
On the other hand, when the gas flows back into the arc volume 9 after having been
cooled, it has a more focused direction, substantially perpendicular to the arc 11c,
in other words it forms more focused beams. The number of beams depends on the number
of gas guide surfaces. These beams quench the arc faster because of their lower temperature
and their "focused" shape.
[0041] In other words, the heating channel comprises at least one gas guide surface with
the first end section 12a guiding gas into the arc volume 9 and the second end section
12b guiding gas into the heating volume 8, wherein the first and the second end sections
12a, 12b are located at delimiting walls 3a, 6 of the heating channel 16 and are arranged
in such a way that gas flows into the arc volume 9 in a substantially radial direction
ρ and into the heating volume 8 in a partially azimuthal direction ϕ in respect to
the longitudinal axis z, respectively.
[0042] Fig. 5 shows four embodiments of a combination of the insulating nozzle 1 and the
auxiliary nozzle 5. The reference numerals in Fig. 5a are valid for Fig. 5b and those
of Fig. 5c are valid for Fig. 5d. All embodiments of Fig. 5 are seen from "inside"
the heating volume 8 against the direction of the longitudinal axis z. The embodiments
of Fig. 5a and 5b are shown in a perspective view, wherein the dotted circles denote
far ends of the respective nozzle and the solid lined circles close ends of the respective
nozzle. Thus, the bigger grey ring represents the inner wall 3a of the insulating
nozzle 1 and the smaller grey ring represents the outer wall 6 of the auxiliary nozzle
5. The white ring indicates the heating channel 16. Fig. 5c and 5d show for reasons
of clarity only a sectional view of both nozzles 1, 5, wherein the white ring again
denotes the heating channel 16.
[0043] In the embodiment of Fig. 5a, both the insulating or main nozzle 1 and the auxiliary
nozzle 5 each comprise eight fins 4 and accordingly sixteen gas guide surfaces 3c.
In the embodiment of Fig. 5b, both the insulating and the auxiliary nozzle 1, 5 each
comprise eight grooves 3b and accordingly sixteen gas guide surfaces 3c. The arrows
A and B again denote the exit direction of the insulating gas from the gas guiding
channel into the respective volume.
[0044] It is useful to use multiple fins 4, arranged at the inner wall 3a around the wide
section 3 of the insulating nozzle 1, which are alternately concave and convex. By
this arrangement, a type of wind channel for the gas is created by two neighbouring
fins. An example is shown in Fig. 5c or 5d.
[0045] In the embodiment of Fig. 5c, the insulating nozzle 1 comprises sixteen fins 4 with
thirty-two rounded gas guide surfaces 3c and the auxiliary nozzle 5 comprises eight
grooves 3b with sixteen rounded gas guide surfaces 3c. The embodiment of Fig. 5d shows
a variant of the embodiment of Fig. 5c with oblique gas guide surfaces 3c. Here, only
the direction of gas exiting into the heating volume 8 is indicated for reasons of
clarity. It can be seen that the fins and the grooves of the embodiments of Fig. 5c,
5d have been grouped to form a wind-tunnel-like gas guiding channel.
[0046] In all embodiments of the invention with more than two fins and/or grooves, the fins
or grooves, respectively, are arranged at predefined mutual distances, wherein each
mutual distance may be different or the distances may be equal.
[0047] In the case of using fins 4, the height of a fin in a direction perpendicular to
the wall it is attached to or it is a part of can be chosen on the heating volume
8 side such that a free gas tunnel is remaining, which is not delimited by the fins
4 and which can be located substantially in the middle of the heating channel 16.
This advantageously allows a portion of the gas to flow into the heating volume 8
in the usual direction, whereas the rest of the gas flows in with azimuthal momentum.
On the other hand, on the arc volume 9 side the fins may be as high as to completely
tunnel the gas flowing into the arc volume in order to focus the entire gas amount.
Thus, this embodiment leads to such a shape of the fins 4 that, when travelling from
the heating volume 8 towards the arc volume 9, the height of the fins 4 increases.
In other words, in terms of the coordinate system of Fig. 3, the ρ component of the
upper fin edge decreases.
[0048] Fig. 6 shows two further embodiments. In the embodiment of Fig. 6a (section 6a of
Fig. 6), the second portion 14b of the fin 4, or the second end section 12b, extends
into the heating volume 8. This example only shows a single fin 4 arranged at the
inner wall 3a of the insulating nozzle 1 which is shown here as a simple cylinder
for clarity reasons, and another fin arranged at the outer wall 6 of the auxiliary
nozzle 5. However, multiple fins 4 and/or grooves 3b may be used.
[0049] In the embodiment of Fig. 6b (section 6b of Fig. 6), the end face 3d of the insulating
nozzle 1 facing the heating volume 8 is formed as or has attached to it at least one
protrusion 15 which extends into a flow C of the insulating gas. Of course, this embodiment
may be applied on the arc volume side of the insulating nozzle 1 and for both end
faces of the auxiliary nozzle 5, as well. In this embodiment, the gas guide surface
is not formed by gas guiding channels extending throughout the heating channel 16,
but the gas guide surface is rather formed only at the end of the heating channel
16. This advantageously saves material for gas guide surfaces and makes it easier
to build the respective nozzle (main nozzle 1 and/or auxiliary nozzle 5).
[0050] The present invention enhances the gas mixing in the heating volume and at the same
time focuses the gas on the arc volume side such that a more effective quenching of
electric arcs in self blast circuit breakers or puffer circuit breakers is obtained.
In other words, the gas guide surfaces act at the same time as a whirl breaker on
the arc volume side and as a whirl producer on the heating volume side. This leads
to energy saving and slows down the wear of components, as for example the contacts,
thus making the circuit breaker more reliable and easier to maintain.
Reference numeral list
[0051]
- 1
- = insulating nozzle
- 2
- = narrow part of insulating nozzle
- 3
- = wide section of insulating nozzle
- 3a
- = inner wall of insulating nozzle
- 3b
- = gas guiding channel, gas guiding groove
- 3c
- = gas guide surface of groove
- 3d
- = end face of insulating or main nozzle
- 3f
- = bottom part of insulating nozzle
- 3g
- = groove extension
- 4
- = fin
- 4a
- = gas guide surface of fin
- 4b
- = end face of auxiliary nozzle
- 4c
- = front face of auxiliary nozzle
- 4d
- = inner circle
- 4e
- = elongated part of fin
- 4f
- = front head part of fin
- 4g
- = oblique part of fin
- 5
- = auxiliary nozzle
- 6
- = outer wall of auxiliary nozzle
- 6a
- = outer wall of additional fin segment
- 7a-7d
- = correspondence arrows (dashed)
- 8
- = heating volume
- 9
- = arc volume
- 10
- = self blast circuit breaker, puffer circuit breaker
- 11a
- = first contact
- 11b
- = second contact
- 11c
- = electric arc
- 12a
- = first end section
- 12b
- = second end section
- 13
- = additional segment of auxiliary nozzle
- 14a
- = first portion of fin
- 14b
- = second portion of fin
- 15
- = protrusion
- 16
- = heating channel
- A
- = gas flow direction into heating volume
- B
- = gas flow direction into arc volume
- C
- = flow of insulating gas
- O
- = origin of coordinate system
- P
- = arbitrary point
- Z
- = longitudinal axis
- ρ
- = radial coordinate
- ϕ
- = azimuth angle
- ω
- = vector
1. Self blast circuit breaker or puffer circuit breaker (10) with at least a first and
a second contact (11a, 11b) for coupling and decoupling an electric circuit, which
are movable relatively to one another in a direction parallel to a longitudinal axis
(z) of the circuit breaker (10) and are meeting in an arc volume (9) inside of which
an electric arc (11c) between the first and the second contact (11a, 11b) develops
when the first and the second contact (11a, 11b) separate, comprising
an insulating nozzle (1),
a heating volume (8),
a heating channel (16) connecting the arc volume (9) to the heating volume (8),
wherein the arc volume (9) and the heating volume (8) are filled with an insulating
gas, whereby
the heating channel (16) comprises at least one gas guide surface (3c, 4a), characterized by said gas guide surface having
a first end section (12a) guiding gas into said arc volume (9), the first end section
(12a) having first means for guiding a gas flow into the arc volume (9) without azimuthal
component with respect to said longitudinal axis (z), and
a second end section (12b) guiding gas into said heating volume (8), the second end
section (12b) having second means for generating an azimuthal component with respect
to the longitudinal axis (z) in a gas flow entering the heating volume (8), wherein
the first and second end sections (12a, 12b) are located at delimiting walls (3a,
6) of the heating channel (16).
2. Circuit breaker according to claim 1, wherein the first means comprise a shape and/or
arrangement and/or element of the first end section (12a) without azimuthal component
with respect to said longitudinal axis (z).
3. Circuit breaker according to any of the preceding claims, wherein the first end section
(12a) is oriented radially with respect to the longitudinal axis (z).
4. Circuit breaker according to any of the preceding claims, wherein the second means
comprise an at least partially azimuthal shape and/or arrangement and/or element of
the second end section (12b).
5. Circuit breaker according any of the preceding claims, wherein the second end section
(12a) is oriented at least partially transversely with respect to the longitudinal
axis (z).
6. Circuit breaker according any of the preceding claims, wherein the insulating nozzle
(1) and the heating volume (8) are arranged concentrically to the longitudinal axis
(z), and in particular wherein the heating volume (8) is arranged beyond an end face
(3d) of the insulating nozzle (1) around the first contact (11a).
7. Circuit breaker according to any of the preceding claims, wherein the gas guide surface
(3c, 4a) is arranged at an inner wall (3a) of the insulating nozzle (1), and the first
end section (12a) and/or the second end section (12b), in particular the entire gas
guide surface (3c, 4a), is formed
as a groove (3b) in the inner wall (3a), and/or
by means of a fin (4), in particular wherein the fin (4) is either attached to or
is part of the inner wall (3a).
8. Circuit breaker according to claim 7,
wherein multiple gas guide surfaces (3c, 4a) are arranged at the inner wall (3a) of
the insulating nozzle (1).
9. Circuit breaker according to any of the preceding claims, comprising an auxiliary
nozzle (5) arranged concentrically around the longitudinal axis (z) between the first
contact (11a) and the insulating nozzle (1), wherein the gas guide surface (4a) is
arranged at an outer wall (6) of the auxiliary nozzle (5), and the first end section
(12a) and/or the second end section (12b), in particular the entire gas guide surface
(4a), is formed
as a groove (3b) in the outer wall (6), and/or
is delimited by means of a fin (4), in particular wherein the fin (4) is either attached
to or is part of the outer wall (6).
10. Circuit breaker according to claim 9, wherein multiple gas guide surfaces (4a) are
arranged at the outer wall (6) of the auxiliary nozzle (5).
11. Circuit breaker according to any of the preceding claims, wherein the second end section
(12b) of the gas guide surface (4a) extends into the heating volume (8).
12. Circuit breaker according to any of the preceding claims, wherein an end face (3d)
of the insulating nozzle (1) facing the heating volume (8) is formed as or has attached
to it at least one protrusion (15) which extends into a stream (C) of the insulating
gas.
13. Circuit breaker according to any of the preceding claims, wherein multiple gas guide
surfaces (4a) are arranged at predefined mutual distances.
14. Circuit breaker according to any of the preceding claims, wherein the gas guide surface
(4a) is rounded, and/or the gas guide surface (4a) is non-radial.
15. Circuit breaker according to any of the preceding claims, wherein the azimuthal component
introduced by the second end section(s) in the gas flow entering the heating volume
(8) generates a full rotation of gas in the heating volume (8), and additional structural
elements are present in the heating volume (8) for breaking up the full rotation of
gas into smaller turbulences.
16. Circuit breaker according to any of the preceding claims, wherein said heating channel
(16) is formed between said walls (3a, 6) of the insulating nozzle (1) and a or the
auxiliary nozzle (5).
1. Selbstblas-Schaltungsunterbrecher oder Puffer-Schaltungsunterbrecher (10) mit wenigstens
einem ersten und einem zweiten Kontakt (11a, 11b) zum Koppeln und Entkoppeln einer
elektrischen Schaltung, die relativ zueinander in einer Richtung parallel zu einer
Längsachse (z) des Schaltungsunterbrechers (10) beweglich sind und in einem Lichtbogenvolumen
(9) zusammentreffen, in dem ein elektrischer Lichtbogen (11c) zwischen dem ersten
und dem zweiten Kontakt (11a, 11b) entsteht, wenn der erste und der zweite Kontakt
(11a, 11b) getrennt werden, der Folgendes umfasst:
eine isolierende Düse (1),
ein Heizvolumen (8),
einen Heizkanal (16), der das Lichtbogenvolumen (9) mit dem Heizvolumen (8) verbindet,
wobei das Lichtbogenvolumen (9) und das Heizvolumen (8) mit einem isolierenden Gas
gefüllt sind, wobei
der Heizkanal (16) wenigstens eine Gasführungsoberfläche (3c, 4a) aufweist,
dadurch gekennzeichnet, dass die Gasführungsoberfläche Folgendes umfasst:
einen ersten Endabschnitt (12a), der Gas in das Lichtbogenvolumen (9) führt, wobei
der erste Endabschnitt (12a) erste Mittel zum Führen einer Gasströmung in das Lichtbogenvolumen
(9) ohne Azimutkomponente in Bezug auf die Längsachse (z) besitzt, und
einen zweiten Endabschnitt (12b), um Gas in das Heizvolumen (8) zu führen, wobei der
zweite Endabschnitt (12b) zweite Mittel zum Erzeugen einer Azimutkomponente in Bezug
auf die Längsachse (z) in einer in das Heizvolumen (8) eintretenden Gasströmung besitzt,
wobei
der erste und der zweite Endabschnitt (12a, 12b) sich an Begrenzungswänden (3a, 6)
des Heizkanals (16) befinden.
2. Schaltungsunterbrecher nach Anspruch 1, wobei die ersten Mittel eine Form und/oder
eine Anordnung und/oder ein Element des ersten Endabschnitts (12a) ohne Azimutkomponente
in Bezug auf die Längsachse (z) aufweisen.
3. Schaltungsunterbrecher nach einem der vorhergehenden Ansprüche, wobei der erste Endabschnitt
(12a) in Bezug auf die Längsachse (z) radial orientiert ist.
4. Schaltungsunterbrecher nach einem der vorhergehenden Ansprüche, wobei die zweiten
Mittel wenigstens teilweise eine Azimutform und/oder eine Anordnung und/oder ein Element
des zweiten Endabschnitts (12b) umfassen.
5. Schaltungsunterbrecher nach einem der vorhergehenden Ansprüche, wobei der zweite Endabschnitt
(12b) wenigstens teilweise quer zu der Längsachse (z) orientiert ist.
6. Schaltungsunterbrecher nach einem der vorhergehenden Ansprüche, wobei die isolierende
Düse (1) und das Heizvolumen (8) konzentrisch zu der Längsachse (z) angeordnet sind,
wobei insbesondere das Heizvolumen (8) jenseits einer Stirnfläche (3d) der isolierenden
Düse (1) um den ersten Kontakt (11a) angeordnet ist.
7. Schaltungsunterbrecher nach einem der vorhergehenden Ansprüche, wobei die Gasführungsoberfläche
(3c, 4a) an einer inneren Wand (3a) der isolierenden Düse (1) angeordnet ist und der
erste Endabschnitt (12a) und/oder der zweite Endabschnitt (12b), insbesondere die
gesamte Gasführungsoberfläche (3c, 4a) geformt sind
als eine Nut (3b) in der inneren Wand (3a), und/oder
mittels einer Rippe (4), wobei insbesondere die Rippe (4) entweder an der inneren
Wand (3a) befestigt ist oder ein Teil hiervon ist.
8. Schaltungsunterbrecher nach Anspruch 7, wobei mehrere Gasführungsoberflächen (3c,
4a) an der inneren Wand (3a) der isolierenden Düse (1) angeordnet sind.
9. Schaltungsunterbrecher nach einem der vorhergehenden Ansprüche, der eine Hilfsdüse
(5) umfasst, die konzentrisch um die Längsachse (z) zwischen dem ersten Kontakt (11a)
und der isolierenden Düse (1) angeordnet ist, wobei die Gasführungsoberfläche (4a)
an einer äußeren Wand (6) der Hilfsdüse (5) angeordnet ist und der erste Endabschnitt
(12a) und/oder der zweite Endabschnitt (12b), insbesondere die gesamte Gasführungsoberfläche
(4a) geformt ist
als eine Nut (3b) in der äußeren Wand (6), und/oder
mittels einer Rippe (4) begrenzt ist, wobei insbesondere die Rippe (4) entweder an
der äußeren Wand (6) befestigt ist oder ein Teil hiervon ist.
10. Schaltungsunterbrecher nach Anspruch 9, wobei mehrere Gasführungsoberflächen (4a)
an der äußeren Wand (6) der Hilfsdüse (5) angeordnet sind.
11. Schaltungsunterbrecher nach einem der vorhergehenden Ansprüche, wobei sich der zweite
Endabschnitt (12b) der Gasführungsoberfläche (4a) in das Heizvolumen (8) erstreckt.
12. Schaltungsunterbrecher nach einem der vorhergehenden Ansprüche, wobei eine Stirnfläche
(3d) der isolierenden Düse (1), die dem Heizvolumen (8) zugewandt ist, als wenigstens
ein Vorsprung (15) ausgebildet ist oder daran befestigt ist, der sich in einen Strom
(C) des isolierenden Gases erstreckt.
13. Schaltungsunterbrecher nach einem der vorhergehenden Ansprüche, wobei mehrere Gasführungsoberflächen
(4a) in im Voraus definierten gegenseitigen Abständen angeordnet sind.
14. Schaltungsunterbrecher nach einem der vorhergehenden Ansprüche, wobei die Gasführungsoberfläche
(4a) abgerundet ist und/oder die Gasführungsoberfläche (4a) nicht radial ist.
15. Schaltungsunterbrecher nach einem der vorhergehenden Ansprüche, wobei die Azimutkomponente,
die durch den oder die zweiten Endabschnitt(e) in die in das Heizvolumen (8) eintretende
Gasströmung eingeleitet wird, eine vollständige Drehung von Gas in dem Heizvolumen
(8) erzeugt und zusätzliche strukturgebende Elemente in dem Heizvolumen (8) vorhanden
sind, um die vollständige Drehung von Gas in kleinere Turbulenzen aufzubrechen.
16. Schaltungsunterbrecher nach einem der vorhergehenden Ansprüche, wobei der Heizkanal
(16) zwischen den Wänden (3a, 6) der isolierenden Düse (1) und einer oder der Hilfsdüse
(5) geformt ist.
1. Disjoncteur à auto soufflage ou disjoncteur à soufflage d'arc (10) comportant au moins
un premier et un second contact (11a, 11b) permettant de coupler et de découpler un
circuit électrique, lesquels sont mobiles l'un par rapport à l'autre dans une direction
parallèle à un axe longitudinal (z) du disjoncteur (10) et qui se rencontrent dans
un volume d'arc (9) à l'intérieur duquel se développe un arc électrique (11c) entre
le premier et le second contact (11a, 11b) lorsque le premier et le second contact
(11a, 11b) se séparent, le disjoncteur comprenant :
une buse isolante (1),
un volume de chauffage (8),
un canal de chauffage (16) reliant le volume d'arc (9) au volume de chauffage (8),
dans lequel le volume d'arc (9) et le volume de chauffage (8) sont remplis d'un gaz
isolant grâce auquel le canal de chauffage (16) comprend au moins une surface de guidage
du gaz (3c, 4a) caractérisée en ce que ladite surface de guidage du gaz possède une première section d'extrémité (12a) guidant
le gaz à l'intérieur dudit volume d'arc (9), la première section d'extrémité (12a)
comportant un premier moyen permettant de guider un flux de gaz dans le volume d'arc
(9) sans composante azimutale par rapport au dit axe longitudinal (z), et
une seconde section d'extrémité (12b) guidant le gaz dans ledit volume de chauffage
(8), la seconde section d'extrémité (12b) comportant un second moyen permettant de
générer une composante azimutale par rapport à l'axe longitudinal (z) dans un flux
gazeux entrant dans le volume de chauffage (8), dans lequel
les première et seconde sections d'extrémité (12a, 12b) sont situées au niveau de
parois de délimitation (3a, 6) du canal de chauffage (16).
2. Disjoncteur selon la revendication 1, dans lequel le premier moyen comprend une forme
et/ou un agencement et/ou un élément de la première section d'extrémité (12a) sans
composante azimutale par rapport au dit axe longitudinal (z).
3. Disjoncteur selon l'une quelconque des revendications précédentes, dans lequel la
première section d'extrémité (12a) est orientée radialement par rapport à l'axe longitudinal
(z).
4. Disjoncteur selon l'une quelconque des revendications précédentes, dans lequel le
second moyen comprend une forme et/ou un agencement et/ou un élément de la seconde
section d'extrémité (12b) au moins partiellement azimutal.
5. Disjoncteur selon l'une quelconque des revendications précédentes, dans lequel la
seconde section d'extrémité (12b) est orientée au moins partiellement transversalement
par rapport à l'axe longitudinal (z).
6. Disjoncteur selon l'une quelconque des revendications précédentes, dans lequel la
buse d'isolement (1) et le volume de chauffage (8) sont disposés de manière concentrique
par rapport à l'axe longitudinal (z) et en particulier dans lequel le volume de chauffage
(8) est disposé au delà d'une face d'extrémité (3d) de la buse d'isolement (1) autour
du premier contact (11a).
7. Disjoncteur selon l'une quelconque des revendications précédentes, dans lequel la
surface de guidage du gaz (3c, 4a) est disposée au niveau d'une paroi interne (3a)
de la buse d'isolement (1) et de la première section d'extrémité (12a) et/ou de la
seconde section d'extrémité (12b), en particulier toute la surface de guidage du gaz
(3c, 4a) est formée
comme une rainure (3b) dans la paroi interne (3a), et/ou
au moyen d'une ailette (4), en particulier dans laquelle l'ailette (4) est soit fixée
à la paroi interne (3a), soit en fait partie.
8. Disjoncteur selon la revendication 7, dans lequel de multiples surfaces de guidage
de gaz (3c, 4a) sont disposées au niveau de la paroi interne (3a) de la buse d'isolement
(1).
9. Disjoncteur selon l'une quelconque des revendications précédentes, comprenant une
buse auxiliaire (5) disposée de manière concentrique autour de l'axe longitudinal
(z) entre le premier contact (11a) et la buse isolement (1), dans lequel la surface
de guidage du gaz (4a) est disposée au niveau d'une paroi externe (6) de la buse auxiliaire
(5), et la première section d'extrémité (12a) et/ou la seconde section d'extrémité
(12b), en particulier toute la surface de guidage du gaz (4a), est formée
comme une rainure (3b) dans la paroi externe (6), et/ou est délimitée au moyen d'une
ailette (4) en particulier dans lequel l'ailette (4) est soit fixée à la paroi externe
(6), soit en fait partie.
10. Disjoncteur selon la revendication 9, dans lequel de multiples surfaces de guidage
du gaz (4a) sont disposées au niveau de la paroi externe (6) de la buse auxiliaire
(5).
11. Disjoncteur selon l'une quelconque des revendications précédentes, dans lequel la
seconde section d'extrémité (12b) de la surface de guidage du gaz (4a) s'étend dans
le volume de chauffage (8).
12. Disjoncteur selon l'une quelconque des revendications précédentes, dans lequel une
face d'extrémité (3d) de la buse d'isolement (1) faisant face au volume de chauffage
(8) est formée comme au moins une protubérance (15) ou en possède une fixée à elle,
laquelle s'étend dans un écoulement (C) du gaz d'isolement.
13. Disjoncteur selon l'une quelconque des revendications précédentes, dans lequel de
multiples surfaces de guidage de gaz (4a) sont disposées à des distances mutuelles
prédéfinies.
14. Disjoncteur selon l'une quelconque des revendications précédentes, dans lequel la
surface de guidage de gaz (4a) est arrondie et/ou la surface de guidage de gaz (4a)
n'est pas radiale.
15. Disjoncteur selon l'une quelconque des revendications précédentes, dans lequel la
composante azimutale introduite par la ou les secondes sections d'extrémité dans le
flux gazeux entrant dans le volume de chauffage (8) génère une rotation complète de
gaz dans le volume de chauffage (8), et des éléments structuraux supplémentaires sont
présents dans le volume de chauffage (8) pour empêcher la rotation complète du gaz
en des turbulences plus petites.
16. Disjoncteur selon l'une quelconque des revendications précédentes, dans lequel ledit
canal de chauffage (16) est formé entre lesdites parois (3a, 6) de la buse d'isolement
(1) et dans une ou dans la buse auxiliaire (5).