EP2740137A1 - Arrangement comprising a circuit breaker interrupter unit - Google Patents

Abstract

The invention relates to a circuit breaker interrupter unit having a first and a second arcing contact piece (4, 5). A breaker gap (10) is arranged between both arcing contact pieces (4, 5). A switching gas channel leads to the breaker gap (10) and guides the switching gas to one of the switching gas outlet openings (24) in the circuit breaker interrupter unit. Said switching gas channel comprises a first and a second pipe section (12, 13) which overlap each other at least in sections and have discharge openings in their cover surfaces. Continuous discharge openings in the first and in the second pipe sections (12, 13). are axially offset in relation to each other.

Description

description

Arrangement comprising a circuit breaker breaker unit

The invention relates to an arrangement comprising a circuit breaker interrupter unit with a switching path arranged between a first and a second arcing contact piece and a switching gas channel opening on the one hand in the switching path and on the other hand in a switching gas outflow opening of the circuit breaker unit, which is at least partially separated from a first and a second pipe section. which overlap each other in the axial direction in an overlapping portion is limited and each have discharge openings in their lateral surfaces.

Such an arrangement is known for example from German Utility Model DE 1 889 068. There, a circuit breaker breaker unit is referred to as a tube extinguishing chamber, which between arcing contact pieces a

Switching path has. To make contact to the outside in the switching path of the switching gas generated, the local Anord ^¬ voltage is equipped with a switching gas channel which a ^¬ hand, in the switching gap, and on the other hand a gas outflow port in switching opens the local pipe extinguishing chamber. Of the

Switching gas channel is partially limited by several Rohrabschnit ^¬ th overlap each other in an axial direction and form an overlap section. In the Mantelflä ^¬ surfaces of the pipe sections each discharge openings are arranged.

In this case, the use of a plurality of pipe sections is provided in the known arrangement, which each have a number of relief openings, which are each arranged in the axial direction in alignment in the respective lateral surface. The pipe sections are arranged coaxially to an axis, wherein the discharge openings of the individual pipe sections are rotated about the axis to each other. An un- indirect violation of switching gas from a discharge ^¬ opening in another discharge opening is prevented. Thus, a frequent deflection of the switching gas is enforced. Although this achieves a good swirling of the switching gas, the flow resistance of the switching gas channel also increases as a result.

A high flow resistance precludes rapid discharge of large amounts of switching gas.

In that respect, an object of the invention an arrangement with a circuit breaker interrupter unit for For such ^¬ form that switching gas can be discharged efficiently. According to the invention, this object is achieved in an arrangement of the type mentioned in that freely continuous discharge openings are arranged axially offset from each other in the first and in the second pipe section. A circuit breaker breaker unit is the part of an electrical switching device. The circuit breaker interruption unit has active parts of the electrical switching device in order to interrupt an electrical current or to switch on an electric current. The Leistungsschalterunter- interrupter unit has for this purpose, for example Lichtbogenkon ^¬ clock pieces are taken to which is typically formed during switching turn-on or Ausschaltlichtböen. In addition to the arcing contact pieces, rated current contact pieces can furthermore be provided, so that the functionality of current carrying and of arc guiding is divided between the rated current contact pieces and the arcing contact pieces. Between the arcing contact pieces, a contact gap is formed, within which a switching or off ^¬ Einschaltlichtbogen is guided. The bridge serves a Schaltstre- inducing galvanic contact with the arcing contact pieces and a separation of the Lichtbo ^¬ genkontaktstücke. The arcing ^contact pieces are designed relative to each other movable relative to each other. The switching gas channel opens thereby in the switching path, so that in the switching path ent ^¬ standing switching gas can be removed from the switching path. The absence of such switching gas channel, it could generate gas by switching in the switching path at ei ^¬ nem come to an undesirable pressure increase, leading to a destruction of the power switch interrupter unit füh ^¬ ren may ultimately. Switching gas can ge ^¬ be neriert example, because of ther ^¬ mix effect of an arc of an isolator. Furthermore, the switching gas can also be generated by evaporation of solids such as insulating materials or conductor materials. The switching gas is ^{üblicherwei ¬} se excessive in its temperature and experiences due to the temperature increase and an increase in volume. In the switching path, for example, an electrically iso ^¬ lierendes fluid is located, which flows through the switching path ^¬ and surrounds the electrically active parts of the interrupter unit. The electrically insulating fluid serves egg ^¬ nem electrical insulation of the active parts and flows through the circuit breaker breaker unit. Such fluid has the advantage that after an occurrence of an electric arc ^¬ an arc channel is automatically refilled with unkontami- ned electrically insulating fluid. One speaks of a so-called self-healing electrical isolation. As the electrically insulating fluid are ^¬ example, electrically insulating gases or electrically insulating fluids such as oils, esters, etc. can be used. Suitable electrically insulating gases have proven to be sulfur hexafluoride, nitrogen and mixtures with these gases. Advantageous adhesive enough, the electrically insulating fluid under ei ^¬ nem overpressure should standing wash around the Leistungsschalterunterbrecherein- unit. By the excess pressure, the electric Iso ^¬ lationsfestigkeit of the fluid is increased. The switching gas channel opens into the switching path and connects the switching path with a switching gas outflow opening, which is located in the periphery of the circuit breaker breaker unit. This can be located in the switching path under pressurized switching gas are passed through the switching gas channel through the interrupter unit through a defined way up to a Schaltgasausströmöffnung to flow there into the environment of the circuit breaker breaker unit. The environment of the circuit breaker breaker unit is filled, for example, with a fluid, with wel ^¬ chem flowing out of the Schaltgasausströmöffnung

Switching gas can be swirled and mixed. This fluid may be identical to and in communication with the fluid within the circuit breaker unit. The switching gas channel can be performed circuit- breaker interrupter unit within the performance, for example, within ei ^¬ nes overlapping portion, which is formed by overlapping two pipe sections. The overlap portion extends in an axial direction. Since ^¬ at, a first pipe section has a smaller cross-section than a second tube portion so that außenman- telseitig the inner first pipe section and innenmantelsei- tig at the outer second pipe section, an annular exhaust section of the switching gas channel is limited, which corresponds to the operation and control of the switching gas can serve. Thus, the switching ^¬ gas channel in the overlapping region of the pipe sections on an annular cross-section. Advantageously, the pipe sections should each have similar cross sections, so that an annular cross section is formed with parallel body edges. Preferably, the Rohrab ^¬ sections each annular cross-sections should have, so that the limited area in the overlapping portion of the

Switching gas channel has a circular cross-section. The pipe sections should have similar cross-sections in the region of their overlap. By an arrangement of relief opening in the lateral surfaces of the pipe sections, the possibility is given, in addition to an axial guidance of switching gas within the pipe sections to allow a radial outflow of the switching gas through the walls of the Rohrab ^¬ sections. An axial offset of the discharge openings in the first and in the second pipe section to each other, allows a radial escape of switching gas through the discharge openings, wherein a direct escape of switching gas from a discharge opening of a pipe section is prevented in a discharge opening of the other pipe section. This ensures that a discharge opening, which is freely continuous, is covered by a wall of the other pipe section. Furthermore, it is ensured that the switching gas is deflected radially before it flows into a discharge opening, or that the switching gas is axially deflected after it has emerged from a discharge opening.

In a projection in the direction of a direction of passage of a discharge opening so a cover is always given by a wall of the other pipe section. Thus, an impact surface is provided in the direction of passage in front of / behind each free-flowing discharge opening. Thus, an effective swirling and mixing of the switching gas is ensured with located within the switching gas channel insulating fluid. An axial offset may be such ausges ^¬ taltet is that over almost the entire length of the different tube sections each discharge openings are arranged, wherein an axial displacement is constrained by a need wise closing individual discharge openings. In addition, it can also be provided that a group of relief ^¬ openings in the first and in the second pipe section axially spaced to a group of relief openings in the second or in the first pipe section is arranged.

By an axial offset, a flow of switching gas in radial directions is made possible, so that increased Schaltgasmengen can be passed through the Schaltgaskanal through within short time intervals, despite a turbulence and deflection of the switching gas, the flow resistance experiences only a limited Strömungswiderstandserhö ^¬ hung. It can be provided that there are user programmable common relief openings in the axial sequence several times alternately in the first and second pipe section be ^¬. It can also be provided that at the pipe sections only at a front end of the overlap pungsabschnittes having a pipe section freely continuous discharge openings, whereas the other pipe section at the other front end of the Überlappungsberei ^¬ Ches has freely continuous discharge openings. Groups of free-passage discharge openings in the first or in the second pipe section can be located at each of the front ends.

A further advantageous embodiment can provide that with respect to the axial direction within the Überlappungsab ^{¬ section} on an azimuthal path in each case only one of the pipe sections freely continuous discharge ^openings has ^¬ . By the definition of one or more azimuthal webs with respect to the axial direction, to which, for example, hollow cylindrical pipe sections can each be arranged co ^¬ axially as well as allowing continuous discharge openings only at one of the two pipe sections, the assurance is given that radially aligned ^¬ the discharge openings are prevented in the two pipe sections. Thus, an impact wall on / in front of a jewei ^¬ lig continuous relief opening is provided at which a discharge opening from leaking switching gas is deflected and carried an inflow of switching gas in a discharge opening by changing the direction of flow. Thus, an effective swirling and cooling of the switching gas is possible. Furthermore, there is the possibility ge ^¬ give to allow several relief openings on the azimuthal path within a tubular body and thus to allow a redirection of switching gas in many radial directions on the azimuthal path. In order for a large total cross section can be provided by several relief openings available to allow flow through large volumes of switching gas channel through the Schaltgas- and to bring about a favorable Küh ^¬ development. For example, it may be provided that a plurality of azimuthal webs are arranged in the two mutually encompassing pipe sections, which are a radial Allow outgassing of switching gas. These azimuthal webs can be arranged alternately offset in axial direction in the first or the second pipe section. However, it can also be provided that groups of relief openings in the first and in the second pipe section are arranged axially offset from one another, so that a deflection of the switching gas is forced in the radial direction on the first pipe section and then further steering of the switching ^¬ gases in axial direction takes place, in order then then in turn to be able to flow in the radial direction through the discharge opening of the second pipe section.

Besides the use of two mutually engaging around pipe sections, which limit a switching gas passage on the shell side within an overlap portion, a USAGE ^¬ dung for any further number of overlapping pipe sections may be provided so that a plurality of shell-like successive portions of are Schaltgaska ^¬ Nals given, which in The same axially extending overlap region follow each other radially. Correspondingly, when more than two pipe sections are used, the axial offset of freely interspersed relief openings can relate to the pipe sections immediately adjacent to one another, which together delimit a section of a switching gas channel. More not directly be ^¬ neighboring pipe sections may optionally be arranged in alignment on the same azimuthal web have discharge opening, through an intermediate pipe portion, which may be arranged to the other two pipe sections in each case immediately adjacent to a baffle wall is gebil ^¬ det.

A further advantageous embodiment can provide that at least in one of the pipe sections, in particular a plurality of relief openings are closed by a valve body. By using a fitting body, it is possible to close discharge openings in at least one of the pipe sections. It may be provided, for example, that depending on the expected switching gas volumes or to be achieved by cooling output a different number of Entlastungsöff ^¬ calculations are to be effective. By using valve bodies, it is possible to restrict the free continuity of Entlas ^¬ tung openings and allow only a limited number of openings in the relief work Leistungsschalterun- terbrechereinheit. By adapting the fitting body, it is possible to vary their cooling capacity by changing cover or by a variable covering of relief openings at constant pipe sections. Furthermore, by covering discharge openings, the flow behavior of switching gas within the switching gas channel can be controlled. As a fitting body, for example, annular body can be used, which on / or. are pushed into the pipe sections, so that at least one or in particular both pipe sections are covered in sections by one or more annular bodies. Here, the cross section of the tubular body is pos ^¬ lichst form complementary to select the respective pipe section. For example, a fitting body can be seated on a pipe section on the outside of the casing. However, it can also be provided that a fitting body is inserted into the inner shell side into a tubular body. Due to the shape complementarity is a flush concern of the fitting body given to the respective pipe section, so that the most possible sealing completion and closure of relief openings. By varying the dimension of the fitting body, the number of sealed relief openings can be varied. Furthermore, the position of the fitting body can vary relative to the tubular body. Furthermore, it can be provided that at least one fitting body serves to hold or position a pipe section on the circuit breaker breaker unit. Furthermore, it can be advantageously provided that the pipe sections are each encompassed by a fitting body at the ends and the fitting bodies protrude from opposite directions into the overlapping section in such a way that the molding bodies end at a common path running around the axial direction.

The fitting bodies can be arranged, for example, at each end on the two pipe sections, wherein the valve bodies can serve to hold and position the pipe sections. Thus, it is possible to align the two pipe sections, for example by means of the fitting body to coaxially ^¬ each other and set the course of the switching gas ^¬ channel. Are the tube sections now at each end equipped with valve bodies, wherein the valve ^¬ body are disposed respectively at opposite ends with respect to the axial direction of the tubular body, the Mög ^¬ friendliness is given a relief openings closing area of the valve body from opposite ends in an intermediate arranged to the ends of the tubular body, to let run in the central region of the overlapping portion. Thus, in each case oppositely aligned ends, namely each end sides of the pipe sections are spanned or covered by the armature ^¬ turkörper, so that only the not facing away from the valve body sections of the tubular body with the relief openings located there can serve a radial passage of switching gas. The circulating track can be self-contained around the axial direction and have different shapes. For example, the web may etc. have a circular shape, an elliptical shape, a ge ^¬ corrugated shape, a sawtooth shape. The faucets collide from opposite directions in a complementary shape against this path and end at her. For example, the web can circulate azimuthally. Due to the spacing of the tubular body to each other, a juxtaposition of the web is only transverse in one projection, in particular determine radially to the axial direction. The web thus represents a virtual complementary shape shock edge. Schaltgas can so in the area of the circulating path over a short distance from a discharge opening of a pipe section in a discharge ^¬ opening of the other pipe section, wherein the switching gas flow is impressed upon passage over an axial flow direction. At a Aneinan ^¬ derstoßen thus is given to a web the opportunity to cause the switch gas, for example, at first within the first Rohrab ^¬ section centric, since the switching gas because of covering the discharge openings pers means of a Armaturkör- not initially can be redirected in radial directions, and only at the subsequent section in the radial direction can flow around. A further radial flow of the switching gas is prevented by the second pipe section or by the fitting body, which covers relief openings located in the second pipe section. So in turn forced to ^¬ next axial currents. According to a radial deflection in turn can be provided by Entlastungsöff ^¬ voltages within the second tubular body after passing the cover of the second valve body. Thus, a deflection of the switching gas can be forced by 180 °, wherein the switching gas channel has a meandering course.

By using valve bodies, it is possible, for example, to have discharge openings throughout

Partially cover tube body by means of the valve body, said valve bodies each in the axial direction only span a portion of the entire overlapping portion of the two Rohrab ^¬ sections.

A further advantageous embodiment may provide that at least one of the pipe sections comprises a perforated plate with symmet ^¬ driven located in the pipe section discharge openings.

The use of perforated plates makes it possible to mold standardized tubular body and in whose jacket surface a mög ^¬ lichst symmetric distributing a plurality of dismissal openings. For example, Entlas ^¬ tung openings can structure the perforated plate grid-like manner, so that a plurality of intersecting ridges formed between the relief openings which ensure a torsional rigidity of the tubular body. For example, the Ent ^¬ lastungsöffnungen may be distributed to each azimuthal paths symmetrically, wherein the discharge openings are aligned linearly aligned in the axial direction. In the case ^¬ sem the ridges cross each other at right angles. However, it can also be provided that the distribution of relief openings on immediately adjacent azimuthal paths is offset relative to one another. In this case, the webs do not cross at right angles. A tubular body can be formed, for example, by rolling, bending, etc. of a perforated sheet metal plate.

A further advantageous embodiment can provide that the circuit breaker breaker unit is surrounded by a Kapse ^¬ ment housing.

The arrangement of a circuit breaker interrupter unit in ^¬ within an encapsulating makes it possible to design the Kapse ^¬ ment housing fluid-tight, so that the power switch interlock unit is flushing or flushing through electrically insulating fluid is encapsulated and a sporadic volatilization of this electrically insulating fluid is largely suppressed. The encapsulating housing thus constitutes a barrier to the electrically insulating fluid and can also be designed as a pressure-resistant encapsulating housing, so that an electrically insulating fluid enclosed in the interior of the encapsulating housing can also be acted upon with an increased pressure relative to the surroundings of the encapsulating housing. The encapsulating housing surrounds the circuit breaker interrupter unit, the interior of the encapsulating housing defining the surroundings of the circuit breaker interrupter unit. The switching gas channel, which connects the switching path to an environment of the circuit breaker breaker unit, thus provides a connection of Switching path via the switching gas channel and the Schaltgasaus ^¬ strömöffnung with the interior of the hermetically sealed encapsulating. This is a possibility given from the interior of the circuit breaker breaker unit

Switching gas relatively quickly to flow into the environment of the circuit breaker unit and pre-cool the switching gas in this way, so that outside the circuit breaker breaker unit within the Kapse ^¬ ment housing further vortexing, mixing and cooling of the already pre-cooled switching gas with the housing in the Kapse ^¬ ment located electrically insulating fluid can take place.

The encapsulating housing should be designed such that the phase conductors can be inserted through the Kapselungsge ^¬ housing through same into the interior of electrically insulated to be contacted there with the arcing contacts so that a current path can be interrupted or switched on, wherein the arrangement is located with the circuit breaker unit in an electrical power transmission ^¬ network. The circuit breaker interrupter unit should thereby be electrically insulating encapsulating the abge ^¬ supports. For this purpose, the encapsulating ^housing can be designed to be at least ^partially cut-off itself, for example electrically insulating. However, it can also be provided that the encapsulating is formed at least partially from elekt ^¬ rically conductive preferably leading earth potential material, with respect to these electrically conductive sections, the circuit breaker breaker unit should for example be supported electrically insulated by support insulators abge ^¬ .

In the following an embodiment of the invention is shown schematically in a drawing and described in more detail below.

It shows the Figure shows a section through an arrangement with a circuit breaker breaker unit, which is arranged in a Kap ^¬ selungsgehäuse. The figure shows a partially cutaway arrangement with a circuit breaker breaker unit, which is arranged within a capsule housing 1. The Kapselungsge ^¬ housing 1 has present on a metallic molded body, which carries ground potential. The interior of the encapsulating housing 1 is filled with an electrically insulating fluid, preferably an electrically insulating gas such as sulfur hexafluoride or nitrogen or a mixture with the gases. The electrically insulating fluid is beauf beat ^¬ with overpressure. Due to the hermetically sealed design of the encapsulating housing 1, sporadic volatilization of the electrically insulating fluid under overpressure is only possible with difficulty.

The encapsulating housing 1 extends in a substantially tubular manner coaxially to a longitudinal axis 2, wherein the end faces of the encapsulating housing 1 are closed by hood-shaped ^{Verschlussele ¬} elements. The longitudinal axis 2 defines an axi ^¬ ale direction. Furthermore, on the encapsulating housing 1 at ^¬ end flanges, of which a EXEMPLARY shear flange 3 is shown in the figure. By means of the connecting flanges, it is possible to gain access to the interior of the encapsulating housing 1, wherein all connecting flanges are sealed fluid-tight under operating conditions.

In the interior of the encapsulating housing 1 is a Leistungsschalterunter- extends Wesent ^¬ union coaxially to the longitudinal axis 2 interrupter unit. The circuit breaker breaker unit has a first arcing contact piece 4 and a second arcing contact piece 5. The two arcing contact pieces 4, 5 are formed opposite to each other and displaceable along the longitudinal axis 2, wherein the arcing contact pieces 4, 5 aligned substantially coaxially to the longitudinal axis 2 are. The first arcing contact piece 4 is formed bolt-shaped. The second arcing contact piece 5 is shaped like a bush in opposite directions. The first arcing contact piece 4 is assigned a first rated current contact piece 6. The second arcing contact piece 5 is a second

Rated current contact piece 7 assigned. The two clock Nennstromkon- pieces 6, 7 are coaxial to the two Lichtbogenkon ^¬ clock pieces 4, 5 and have the form of complementary Kon ^¬ clock domains on. The first arcing contact piece 4 and the second rated current contact piece 7 and the second arcing contact piece 5 and the second rated current contact piece 7 are permanently contacted with each other electrically conductive, so that the first arcing contact piece 4 and the first rated current contact piece 6 and the second arcing contact piece 5 and the second rated current contact piece 7 permanently the same lead electrical potential.

The two arcing contact piece 4, 5 are arranged displaceable relative to the longitudinal axis 2. For this purpose, it is provided that the first arcing contact piece 4 is equipped with a gear 8, so that the two arcing contact pieces 4, 5 are always movable in the opposite direction. The first rated current contact piece 6 is not displaceably mounted with respect to the longitudinal axis 2. Only the second rated current contact piece 7 is arranged displaceably along the longitudinal axis 2. A relative movement of the arcing contact pieces 4, 5 and the rated current contact pieces 6, 7 to each other is synchronized ^¬ such that at a power-up initially the arcing contact pieces 4, 5 contacting each other and subsequently the rated current contact pieces 6, 7 einan ^¬ contact. During a disconnection first separation of the rated current contact pieces 6, 7, separation of the Lichtbogenkontaktstü ^¬ blocks 4, 5 is carried out takes place whereas represents ^¬ on the following time. Such a synchronization of the movements of arcing contact pieces 4, 5 and rated current contact pieces 6, 7 ensures that an arc is preferably conducted between the arcing contact pieces 4, 5. An arc can be a Einschaltlichtbogen or a Ausschaltlichtbogen, which optionally ignites at a switch-on or a switch-off. In this way, the arcing contact pieces 4, 5 protect the rated current contact pieces 6, 7 against erosion by an arc.

Coaxial with the two arcing contact pieces 4, 5, a Isolierstoffdüse 9 is arranged. The insulating material nozzle 9 is connected in a rigid angle with the second arcing contact piece 5 and has an insulating nozzle channel. The insulating ^¬ nozzle channel defining a between the Lichtbogenkontaktstü ^¬ CKEN 4, 5 formed switching section 10. In the off state, as shown in the figure, projecting the first arc ^¬ contact piece 4 at least partially in the Isolierstoffdüsen- the insulating material 9 canal. In a switching operation, it is thus preferable to guide an arc limited by the insulating material nozzle 9 in the switching path. Generated by an arc, heated and enlarged in volume switching gas preferably flows from the switching path 10 in the direction of the first Lichtbogenkontaktstü ^¬ ckes 4 from. In order to convey an outflow in this direction, the Isolierstoffdüsenkanal the insulating material 9 is trich ^¬ terförmig extended in the direction of the first arcing contact piece 4.

The first rated current contact piece 6 is supported by a pipe socket 11. The pipe socket 11 surrounds the first arcing contact piece 4. In the pipe socket 11 and the remote from the second arcing contact piece 5 free end of the insulating material 9 protrudes into it. In the switching path 10 opens a switching gas channel, which is continued after the Isolierstoffdüse 9 via the pipe socket 11 in the axial direction. The pipe socket 11 thus forms a coaxial with the longitudinal ^¬ axis 2 lying portion of the switching gas channel, wherein projecting into this portion of the switching gas channel, the first arc Kon ^¬ tact piece 4 and the gear 8. At the pipe socket 11, a first pipe section 12 connects. The first pipe section 12 is formed as a hollow cylinder, wherein its lateral surfaces are penetrated by discharge openings. The first pipe section 12 and parts of the pipe socket 11 are encompassed by a second pipe section 13. Also, the second pipe section 13 has over its entire length on the shell side discharge openings. Both the first pipe section 12 and the second pipe section 13 are ^¬ surrounded by a third pipe section 14, wherein the third pipe section 14 serves as a phase conductor for contacting the first arcing contact piece 4 and the first rated current contact piece 6 and both the first arc ^¬ contact piece 4 and the first rated current contact piece 6 and enclosed components, such. B. the first and second pipe sections 12, 13, positioned. The third pipe section 14 is, for example, electrically isolated by a support insulator 15 on the capsule housing 1. Furthermore, the third pipe section 14 on the shell side on a radially outwardly projecting socket 16. By means of this plug ^¬ socket 16 of the third tube section 14 can be contacted via an electrically isolated by the exemplary connection flange 3 in the interior of the encapsulating housing initiated Anschlusspha- senleiter electrically. For this purpose, for example, an electrically insulating and fluid-tight designed free ^¬ air duct can be placed on the exemplary connection flange 3. This makes it possible to integrate the circuit breaker ^{interrupter unit} under Freiluftbedingun ^¬ gen in an electric power transmission network.

The interior of the third pipe section 14 is divided by the two ^¬ th pipe section 13 and the first pipe section 12 into a plurality of hollow cylindrical sub-volumes encompassing each other. Between the first pipe section 12 and the second pipe section 13, a first hollow cylindrical partial volume 17 is arranged. Between the second pipe section 13 and the third pipe section 14, a second hollow-cylindrical partial volume 18 is arranged. The two hohlzylind ^¬ step subvolumes 17, 18 surround a centrally positioned, umgriffenes from the first pipe portion 12 ZENTRA ^¬ les cylinder volume 19th The switching path 10 facing the end of the first Rohrab ^{¬ section} 12 is frontally connected flush with the pipe socket 11. The end remote from the switching path 10 end of the first pipe section 12 is closed by a closure element 20 frontally. The closure element 20 serves as a deflecting body in order to redirect switching gas flowing into the switching gas channel in the axial direction along the longitudinal axis 2 from the switching path 10 into radial directions. At its end of the switching path 10 end of the first pipe section 12 is encompassed by a fitting body 21. The fitting body 21 serves to connect the first pipe section 12 to the pipe socket 11 and surrounds the pipe body to the outer shell side. The valve body 21 is pushed so far hollow-lindrisch to the outer contour of the first tubular section 12, that nearly half of the first Rohrabschnit ^¬ tes 12 are spanned by the valve body 21 and in this section lying discharge openings through the valve body 21 closed. The valve body 21 terminates at an azimuthal path 22. The not spanned by the valve body 21 portion of the first pipe section 12 has to be ^¬ nem facing away from the switching path 10 in freely continuous unloader ports which enable a radial deflection of the switching gas.

The second pipe section 13 is also held by a fitting ^¬ body 23. The fitting body 23 is arranged at the end remote from the switching path 10 end of the second Rohrab ^{¬ section} 13 and surrounds the second pipe section 13 outer shell side, wherein the fitting body 23 extending in the direction of the contact gap 10, außenmantelsei ^{¬ term} flush to the second pipe section 13 applies and there located relief openings closes. The fitting body 23 extends in the direction of the switching path 10, up to the azimuthal path 22, at which the fitting body 21, which surrounds the first pipe section 12 ends. So ^¬ are the free ends of the valve body 21, 23, which in each case in the direction of a center of the Uberlappungsabschnit- Tes of the two tubular body 12, 13 protrude, ending at a vertical plane, formed abutting the azimuthal web 22. Thus, the discharge openings, which are arranged freely continuously on the first pipe section 12, the outside spanned by a baffle, whereas in the second

Tube section 13 located shell-side Entlastungsöff ^¬ tions in turn are spanned in the radial direction on the inside of a baffle. This ensures that ra ^¬ Diale discharge openings in the first and second pipe portions 12, 13 are arranged in the respective tube ^¬ sections 12, 13 offset in the axial direction are arranged to each other.

In the present case, a plurality of groups of relief openings are formed in the first and second pipe sections 12, 13, wherein each individual relief opening of the respective group is offset axially relative to each individual relief opening of the respective other group with respect to the longitudinal axis 2. The relief openings themselves can be arranged in a multiplicity of radial directions in the lateral surface of the respective pipe section 12, 13.

The overlapping section between the first pipe section 12 and the second pipe section 13 is closed at each end, so that an entry or exit of switching gas in the section of the switching gas channel, which in Überlap ^¬ pungsabschnitt with annular cross-section between the ^¬ pipe sections 12, 13th is formed, only from radial directions in the same inflow or can flow in radia- len directions from the same. An inflow and outflow into the portion of the switching gas channel with ringför ^¬-shaped cross-sections carried out in radial directions. In order for a deflection of the switching gas at least once by 180 ° he ^¬ forced, in the interest of a large gas flow abutting the axial offset of relief openings as possible limited to an azimuthal path 22, where ^{¬ both} sides of this azimuthal path 22 in the axial Direction the staggered free discharge openings extend.

After an exit of the switching gas through the discharge openings of the second pipe section 13 in radial directions, the switching gas radiates against the third pipe section 14, which in the present case has no outflow openings in the radial direction. Instead, an arrangement of a plurality of switching gas outflow openings 24 is provided on the front side at the end remote from the switching path 10, which allows escape of switching gas from the circuit breaker breaker unit into the surroundings of the circuit breaker breaker unit. However, it can also be provided that in the third pipe section 14 radially aligned Schaltgasaus- flow openings are arranged.

Thus, via the switching gas channel, which opens on the one hand in the switching path 10, via the discharge openings in the two pipe sections 12, 13, as well as the pipe sections 12, 13 even up to the Schaltgasausströmöffnungen 24 a direct route from the switching path to the environment of Leisten Switch breaker unit, ie, given to the encapsulated by the Kap ^¬ selungsgehäuse 1 volume. Thus, a relieving pressures that may arise in the contact gap during a switching process, carried out in the surrounding environment ^¬ the circuit breaker interrupter unit so that an irreversible effect on the circuit breaker interrupter unit is prevented.

Claims

claims

1. Arrangement comprising a circuit breaker breaker unit with a between a first and a second arcing contact piece (4, 5) arranged switching path (10) and on the one hand in the switching path (10) and on the other ^¬ in a Schaltgasausströmöffnung (24) of the circuit breaker unit opening switching gas channel which is at least partially bounded by a first and a second pipe section (12, 13) which overlap each other in the axial direction (2) in an overlapping section, and in their lateral surfaces each have discharge openings,

d a d u r c h e c e n c i n e s that

freely continuous discharge openings in the first and in the second pipe section (12, 13) are arranged offset from each other axially.

2. Arrangement according to claim 1,

d a d u r c h e c e n c i n e s that

With respect to the axial direction within the Überlappungsab ^{¬ section} on an azimuthal path (22) in each case only one of the pipe sections (12, 13) freely continuous discharge ^¬ openings has.

3. Arrangement according to claim 1 or 2,

d a d u r c h e c e n c i n e s that

at least in one of the pipe sections (12, 13) one, in particular ^¬ special, several relief openings of a valve body (21, 23) are closed.

4. Arrangement according to one of claims 1 to 3,

d a d u r c h e c e n c i n e s that

the pipe sections (12, 13) in each case are encompassed by an armature body (21, 23) and the fitting bodies (21, 23) protrude from opposite directions into the overlapping section in such a way that the fitting bodies (21, 23) at a common, around the axial direction circumferential path (22) ends.

5. Arrangement according to one of claims 1 to 4,

d a d u r c h e c e n c i n e s that

at least one of the pipe sections (12, 13) has a perforated plate with symmetrically located in the pipe section (12, 13) discharge openings.

6. Arrangement according to one of claims 1 to 5,

d a d u r c h e c e n c i n e s that

the breaker interrupter unit is surrounded by a Kapse ^¬ lung housing (1).