EP1173862B1 - Switching gas damper for low voltage power circuit breakers - Google Patents

Abstract

The invention relates to a switching gas damper (1) for low voltage power circuit breakers (2) which is arranged as a top part placed above the arcing chambers (6, 7, 8) in order to effect additional damping, deionization and cooling of the switching gases. The switching gas damper (1) comprises a cuboidal housing with separate entrance openings for receiving switching gas streams (3, 4, 5) flowing to each arcing chamber (6, 7, 8) of the low voltage power circuit breaker (2). Separate diverting channels (17, 21, 23) are formed by the channel walls (16, 20) and/or by deflecting elements (15, 19), and they lead to the sides of the power circuit breaker (2). By virtue of the variable arrangement of the deflecting elements and diverting channels, it is possible, according to the arising quantities of gas and to the characteristics of the utilized arching chambers, to obtain a plurality of flow paths which are separate from one another and which exhibit various desired damping and cooling characteristics.

Description

The invention relates to a switching gas damper for a multi-pole Low-voltage circuit breaker used for additional Damping, deionization and cooling of the switching gases as Attachment is arranged above the parallel quenching chambers, wherein the attachment is a cuboid housing with a front wall, has a back wall and a lid.

Such a switching gas damper, as it is through the EP 0 437 151 B1 has become known, has the task of Effect of an arc extinguishing device for switching in air Support low voltage circuit breakers. The arc extinguishing device ensures that the Circuit breakers occurring switching arcs without impairment the circuit breaker itself and adjacent Parts of the plant or other assemblies are extinguished. These arc quenchers or quenching chambers have depending on the type, size and required switching capacity the circuit breaker very different designs. Common to all of these institutions is more or less parallel arrangement of sheet steel quenching plates, whereby these quenching plates are perpendicular to the switching arc.

In order to reliably extinguish switching arcs, it is not necessary the resulting switching gases down to room temperature cool. At least when the performance an arc quenching chamber can be fully utilized, therefore gases at a temperature emerge from the quenching chamber, which is significantly above room temperature. So you can Remnants of metal vapor are also carried and there can be a there is some degree of ionization. Whether these appearances are harmless depends on the type of installation of the Circuit breaker. Basically it can be said that a Metal vapor content and restionization all the less the smaller the distance between the outlet openings is permitted the arc quenching chambers and adjacent live ones or grounded components. This distance is an important cost factor in the construction of switchgear, because the dimensions of the switchgear depend on this.

On the other hand, the effort increases when arc quenching chambers be designed so that they are in terms of properties of the leaking switching gases meet the highest requirements. That is why the path has been taken, low voltage circuit breakers to be equipped with standard quenching chambers that result in a required switching capacity in terms of properties the leaking switching gases, however, a compromise between minimum and maximum requirements. For those cases where a circuit breaker is special must be accommodated in a switchgear to save space according to EP 0 437 151 B1 mentioned, additional switching gas damper provided that are common to all quenching chambers.

The well-known switching gas damper forms a hood, all Arcing chambers of the circuit breaker covered. Before that Switching gases can leave the hood, they flow through Cooling grille and an outlet filter. The flow direction of the Switching gases upwards are not affected by this. This can be undesirable if above the circuit breaker there is little space. It also requires collection the switching gases from all quenching chambers in one Space sufficient volume to under all circumstances to avoid an electrical phase flashover.

The object of the present invention is based on this therein, a switching gas damper for low-voltage circuit breakers for additional damping, deionization and cooling the switching gases to create a redirection the shale gases in a natural vertical direction allows different direction and its effectiveness is significantly improved.

The invention solves the problem that the Cover closed and a bottom with separate Inlets for receiving switching gas flows from everyone Arcing chamber of the low-voltage circuit breaker is provided and that each inlet opening is through channel walls and / or deflecting elements formed for the purpose lateral discharge of the switching gas flows is assigned.

It is essential for the invention to create separate discharge channels for the switching gas flows of the individual quenching chambers in a common housing because of the total volume can advantageously be dimensioned small. Through the side Derivation of the switching gas flows becomes every contact with the Avoid rear connection rails of the circuit breaker.

FR 2 511 188 A1 is already a switching gas damper became known for a redirection of the flow direction of switching gases. The switching gas damper can be used as Hood to be formed with its open bottom an arc quenching chamber is placed and opposite this is sealed by grooves or separate sealants. The switching gas damper can also be placed in the housing the arc release chamber be integrated that for guidance the walls for switching gas flow to the housing of the extinguishing chamber belong, but their function only by putting on received a lid. This is common to all versions Shift gas damper a single-pole design for double interrupting contact systems (bridge contacts). In doing so the switching gases of both switching contacts of one pole after opposite Sides in the direction of opposite Connection rails deflected. With circuit breakers, which has a front panel and rear panel Have connections, is not an improvement and resolves not the task.

Another well-known gas damper after the DE 1 104 019 B is also single-pole. It is suitable for circuit breakers with one switching contact per pole and directs the switching gases into two partial flows after separation the sides of each arc quenching chamber. Hence the application this switching gas damper with a multi-pole circuit breaker a widening of the entire switching device require, with a free flow of the switching gases not would be guaranteed. Therefore, this switching gas damper also enables no economical solution to the task.

Within the scope of the invention, three-pole low-voltage circuit breakers are recommended an arrangement where parallel a channel wall to the front wall and parallel to the rear wall arranged another channel wall and thereby in connection formed with a total of three deflection channels are, of which the outside, from the front wall and the back wall limited discharge channels on opposite Sides are closed by a side wall and that of the middle discharge duct bounded on the duct walls is open on both sides is such that the from the outer arcing chambers of the Low-voltage circuit breaker escaping switching gas flows are discharged separately to opposite sides, while the one emerging from the middle chamber Switching gas flow through the middle discharge channel after both Sides out of the switching gas damper. Despite less This results in dimensions of the switching gas damper advantageously long flow paths with correspondingly cheaper Cooling effect on the switching gases.

The deflection elements and channel walls can be different Arranged and designed in such a way. In particular, can the channel walls from the floor to the cover of the switching gas damper extend and the side walls can be on the same side of the switching gas damper can be arranged like the outside Extinguishing chambers, such that the switching gas flows to the outside Extinguishing chambers parallel to the front wall and the rear wall of the switching gas damper to the opposite Side of the low voltage circuit breaker and the switching gas current the middle chamber to both opposite Pages. This arrangement is designed with simple to realize flat wall elements. In particular can the one deflecting element from the floor on one channel wall starting to the cover on the opposite Extend channel wall ending, the further deflecting element arranged in opposite directions, rising in the opposite direction between the channel walls and wherein the side parts are one of the rising ones Arrangement of the deflection elements have an adapted shape, such that that a separation of the switching gas flows of the outer quenching chambers and the middle quenching chamber is effected. Instead of this angled arrangement can the deflection elements over the Inlet openings for guiding the switching gas flows of the outer Arcing chambers arranged parallel to the lid and the floor and can be from one duct wall to another duct wall extend, the separation of the switching gas flows outer quenching chambers and the switching gas flow of the middle Extinguishing chamber on the mutually facing sides of the deflection elements Side parts are arranged.

Otherwise, in the arrangement described above with the deflection elements parallel to the floor and the lid in any height position between the lid and the bottom of the switching gas damper. In particular, a position of the deflection elements in FIG a height of 2/3 of the height of the switching gas damper from the ground removed as suitable.

In the embodiments of the invention described above are separate duct walls and deflection elements intended. However, it can prove beneficial if the deflection elements are simultaneously formed as channel walls and are arranged so that the extinguishing chambers of the outer Low voltage circuit breaker emerging poles Switching gas flows directly to the side, i.e. always on the same Side of the low voltage circuit breaker from the Switching gas dampers are derived from the middle Switching gas stream exiting the quenching chamber above or next to the Deflection elements on both opposite sides of the Shift gas damper is guided. A shortening of the flow paths there is a simplified structure of the switching gas damper in a number of variations. In a The first embodiment of this idea can be the deflection elements extending from the floor to the cover of the switching gas damper be arranged. Preferably, the deflection elements starting from the front wall of the switching gas damper between the inlet openings above the quenching chambers running in the direction of the rear wall, then angled, behind the inlet openings for the switching gases the outer arcing chambers up to the lateral limit of the switching gas damper, be arranged such that between these angled parts of the deflection elements and the rear wall of the switching gas damper one with the room above the middle arcing chamber of the low-voltage circuit breaker connected, on both sides of the switching gas damper open discharge channel for the switching gas flow this middle chamber is formed. Is a low flow resistance desired, the bends of the deflection elements be rounded.

Also can be between the front wall and the rear wall of the Switching gas damper extending deflection elements are provided be that also take over the function of channel walls. This can be done in such a way that the deflection elements extending between the front wall and the rear wall are arranged that each have a discharge channel for an external one Extinguishing chamber through the floor and a deflector limited and between the deflection elements and the lid open on both sides and with the middle entrance opening in the Floor-connected discharge channel for the middle one Extinguishing chamber is formed.

In the context of the invention, the deflection of the laterally guided Switching gas flows parallel to the side walls of the low-voltage circuit breaker through a directional housing with a deflection chamber. This directional housing can be angular be trained.

The switching gas flows can also be deflected by that the cover of the switching gas damper is wider than that Low voltage circuit breakers trained and lateral Limits of the switching gas damper with downward directed Guide elements are provided. Such guidance elements can simple way by extending downward extensions be formed of the side walls of the switching gas damper.

The invention is intended to be described with reference to the associated Drawing, based on, the scope of protection not restricting, preferred embodiments explained in more detail become.

1 shows schematically in a perspective view a first possible embodiment of the invention Switching gas damper in its spatial position to the low-voltage circuit breaker and the flow of switching gases from the quenching chambers of the same through the switching gas damper. 2 shows schematically in a perspective view a second possible embodiment of the invention Switching gas damper and the flow of switching gases through same.

3 shows schematically in a perspective view a third possible embodiment of the invention Switching gas damper in its spatial position Low voltage circuit breakers and the flow of switching gases from the quenching chambers of the same through the switching gas damper.

4 shows a schematic plan view of the switching gas damper 3, the lid has been omitted.

5 shows schematically in a perspective view two variants of a fourth possible embodiment of the switching gas damper according to the invention and the flow of Switching gases through the same.

6 shows a perspective illustration schematically two further variants of the fourth possible embodiment of the switching gas damper according to the invention and Flow of the switching gases through the same.

The switching gas damper 1 according to FIG. 1 is shown schematically in perspective representation in connection with a partial Low-voltage circuit breaker 2 shown. The switching gas damper 1 is one lifted from the circuit breaker 2 Position shown to interact with the Arcing chambers 6, 7 and 8 and the course of the switching gas flows to illustrate.

For further clarification, the closed cover 9 of a front wall 10, a rear wall 11, a right side wall 12, a left side wall 13 and one outside of the inlet openings having closed bottom 14 Switching gas damper 1 shown in a raised position.

A deflection element 15 with a side part 28 forms with one from the bottom 14 of the switching gas damper 1 to the cover 9 the same extending channel wall 16 and the left side wall 13 one open to the right side of the switching gas damper 1 Discharge channel 17. Another deflection element 19 with a invisible side part forms with one from the floor 14 of the switching gas damper 1 up to the cover 9 thereof Channel wall 20 and the right side wall 12 one to left side of the switching gas damper 1 open discharge channel 21. Both discharge channels 17 and 21 are through the lid 9 of the Switching gas damper 1 and closed at the bottom by its bottom 14. Between the deflection elements 15 and 19 and the channel walls 16 and 20 remain due to the inclined, from the bottom 14 to the lid 9 rising arrangement of Deflection elements 15 and 19 free spaces that have a central discharge channel 23 form.

The one from the left extinguishing chamber 6 of the low-voltage circuit breaker 2 emerging switching gas stream 3 passes through the left one, which is not shown because of the better overview Entry opening in the switching gas damper 1. He is through the deflection element 15 in the through the cover 9, the left Side wall 13, the rear wall 11, the channel wall 16 and the bottom 14 formed discharge channel 17 from which it is only on the right side of the switching gas damper 1 can exit, like that is indicated by an arrow 18. The one on the right Arcing chamber 8 of the low-voltage circuit breaker 2 emerging Switching gas stream 5 passes through because of the better Overview of the right entry opening, also not shown in the switching gas damper 1. It is caused by the deflecting element 19 in through the cover 9, the right side wall 12, the front wall 10, the channel wall 20 and the bottom 14 formed Discharge channel 21 passed from which it is only on the left Side of the switching gas damper 1 can emerge like that is indicated by an arrow 22. The one from the middle Arcing chamber 7 of the low-voltage circuit breaker 2 emerging Switching gas flow 4 passes through because of the better Overview also of the middle inlet opening, not shown here in the switching gas damper 1. It goes directly into the through the cover 9, the channel wall 16, the channel wall 20, the Deflection elements 15 and 19 and the bottom 14 formed discharge channel 23, from which he is on both sides of the switching gas damper 1 can emerge, as indicated by arrows 24 and 25 is. To deflect the on the left side of the switching gas damper 1 emerging switching gas flow 3 and the left the switching gas damper 1 emerging part of the switching gas flow 4 (arrow 24) is angled down from one trained directional housing 26 formed deflection chamber 27 is provided, which is attached to the side of the switching gas damper 1.

The deflection chamber 27 is in Fig.1 for better understanding shown at a distance from the switching gas damper 1.

2 shows schematically a second embodiment of a switching gas damper 31 according to the invention and the flow paths the switching gas flows 33, 34 and 35 through the same. For clarification the closed lid 39 of the continued from a front wall 40, a rear wall 41, a right one Side wall 42, a left side wall 43 and one outside of the inlet openings closed floor 44 existing Switching gas damper 31 shown in a raised position. A deflection element 45 does not form together with one visible side part and one from the bottom 44 of the switching gas damper 31 to the cover 39 of the same extending channel wall 46 and a left side wall 43 one to the right Side of the switching gas damper 31 open discharge channel 47. On forms a further deflection element 49 with a side part 56 one from the bottom 44 of the switching gas damper 31 to the cover 39 of the same extending channel wall 50 and the right Side wall 42 one to the left side of the switching gas damper 31 open discharge channel 51. Both discharge channels 47 and 51 are at the top through the cover 39 of the switching gas damper 31 and below closed by its bottom 44. Between the deflection elements 45 and 49 and the channel walls 46 and 50 and the cover 39 remain due to the arrangement of the deflecting elements 45 and 49 free spaces that form a third discharge channel 53.

One from the left extinguishing chamber of the figure 2 for simplification Low-voltage circuit breaker, not shown escaping switching gas stream 33 passes through because of the better Overview of left inlet opening, not shown in the switching gas damper 31 a. It is caused by the deflecting element 45 in the through the cover 39, the left side wall 43, the Rear wall 41, the channel wall 46 and the bottom 44 formed discharge channel 47 headed out of it just on the right of the switching gas damper 31 can emerge, as by the Arrow 48 is indicated.

One from the right quenching chamber of the low-voltage circuit breaker escaping switching gas stream 35 passes through the also not shown because of the better overview right inlet opening in the switching gas damper 31. He is deflected by the deflecting element 49 into the cover 39, the right side wall 42, the front wall 40 the channel wall 50 and the bottom 44 formed discharge channel 51 passed from the he only emerge on the left side of the switching gas damper 31 can, as indicated by arrow 52. On off the middle arcing chamber of the low-voltage circuit breaker escaping switching gas flow 34 occurs due to the A better overview of the central inlet opening, not shown here in the switching gas damper 31. It arrives directly in the through the cover 39, the channel wall 46, the channel wall 50, the deflection elements 45 and 49 and the bottom 44 formed Discharge channel 53, from which it on both sides of the Switching gas damper 31 can emerge, like that by the arrows 54 and 55 is indicated.

3 schematically shows a third embodiment Switching gas damper 61 in its spatial position to one Low voltage circuit breaker 62 and the flow paths of switching gas flows 63, 64, 65 from arcing chambers 66, 67, 68 by the switching gas damper 61. This is according to the Representation in Figure 1 at a spatial distance from Low voltage circuit breaker 62 is shown to the Paths of the switching gas flows 63, 64, 65 from the individual quenching chambers 66, 67, 68 to clarify.

The switching gas damper 61 consists essentially of a closed one Cover 69, from a front wall 70, a rear wall 71, a closed right side wall 72, a closed left side wall 73 and one outside the entry openings closed bottom 74. The switching gas damper In this version, 61 is wider than the low-voltage circuit breaker 62. This achieves that the switching gas flows 63, 64 and 65 to the side of the low-voltage circuit breaker 62 through the closed Side walls 72, 73 are derived downward, as in 4 is explained. For this, the Side walls 72 and 73 with baffles facing downwards or be provided with extensions 128.

The one from the left quenching chamber 66 of the low-voltage circuit breaker 62 emerging switching gas stream 63 passes through the left one, which is not shown because of the better overview Entry opening in the switching gas damper 61. He will led out of the switching gas damper 61 by the deflection element 75 and deflected downward by the left side wall 73, as indicated by arrow 77. The one from the right quenching chamber 68 of the low-voltage circuit breaker 62 emerging switching gas stream 65 passes through because of Right entry opening, also not shown, provides a better overview in the switching gas damper 61. He is through the deflection element 76 is led out of the switching gas damper 61 and also down through the right side wall 72 distracted, as indicated by arrow 78.

The switching gas flow 64 emerging from the middle arcing chamber 67 of the low-voltage circuit breaker 62 enters the switching gas damper 61 through the middle inlet opening, which is also not shown here for the sake of a better overview. It enters the discharge channel 79 formed by the cover 69, the deflection elements 75 and 76 and the base 74, from which it can exit on both sides of the switching gas damper 61. This switching gas stream 64 emerging laterally in two partial streams is also discharged downward through the closed side walls 72, 73, as is indicated by the arrows 80 and 81.
In this embodiment of the switching gas damper 61 according to the invention, the side walls can also be omitted, so that the switching gases can escape laterally unaffected, provided the installation location of the low-voltage circuit breaker 62 is suitable for this.

4 shows schematically a top view of the embodiment of the switching gas damper 61 according to the invention 3, with the lid omitted.

The switching gas damper 61 is wider than that in FIG low-voltage circuit breakers located in a slide-in housing 82 62. This is between a left side wall 83 of the low-voltage circuit breaker 62 and left side wall 73 of the switching gas damper 61 an up closed by the cover 69 of the switching gas damper 61, downwardly open discharge channel 84 is formed.

Likewise, between a right side wall 85 of the low voltage circuit breaker 62 and the right side wall 72 of the switching gas damper 61 an upwards through the cover 69 of the switching gas damper 61 closed, open at the bottom Discharge channel 86 available. Because of the floor 74 to Cover 69 of the switching gas damper 61 extending deflection elements 75 and 76 become three separate switching gas flows 63, 64 and 65 limited.

The one from the left quenching chamber 66 of the low-voltage circuit breaker 62 emerging switching gas stream 63 passes through the left inlet opening 87 into the switching gas damper 61. It is by the deflection element 75 from the switching gas damper 61 led out and through the left side wall 73 of the Shift gas damper 61 deflected downward, like that by one Arrow 88 is indicated. The one from the right fire chamber 68 of the low-voltage circuit breaker 62 emerging Switching gas flow 65 passes through the right inlet opening 89 in the switching gas damper 61. It is caused by the deflecting element 76 led out of the switching gas damper 61 and through the right side wall 72 of the switching gas damper 61 also deflected downward, as indicated by an arrow 90 is.

The one from the middle arcing chamber 67 of the low-voltage circuit breaker 62 emerging switching gas stream 64 occurs through the middle inlet opening 91 in the switching gas damper 61 a. It passes through the cover 69 (removed, 3), the deflection elements 75 and 76, the rear wall 71 and the bottom 74 formed discharge channel 79, from which it opens both sides of the switching gas damper 61 can emerge. Also this switching gas flow emerging laterally in two partial flows 64 is through the closed side walls 72, 73 of Shift gas damper derived downwards, like that through the Arrows 92 and 93 are indicated. Through the rear wall 71 of the Switching gas damper 61 and the lateral derivation of the switching gases become the connecting rails 94, 95 and 96 of the low-voltage circuit breaker 62 before touching the switching gases safely protected.

5 shows schematically in a perspective view two variants of a further embodiment of one switching gas damper according to the invention. The switching gas damper shown 101 has a front wall 110, a rear wall 111 and one outside of entry openings 107 and 108 (one third entry opening is not visible) closed bottom 114 on. A lid 109 is broken off and in a lifted off Position shown.

In the embodiment variant according to the right part of FIG. 5 deflection elements 115 are provided, which are rectangular Parts are formed and to the right side of the switching gas damper 101 open discharge channels 117 for the switching gas flow 103 from the external arcing chambers of the not shown Form low-voltage circuit breakers. The flow direction is indicated by an arrow 122. The variant according to the left part of FIG. 5 has deflection elements 119, which are also as angle elements, but with an angle larger are designed as 90 °. The deflection elements also form 119 open to the left side of the switching gas damper 101 Discharge channels 121 for the switching gas flow 105 from the outside Chutes. Here is the flow direction with indicated by an arrow 118.

In both variants according to FIG. 5 there remain between the Deflection elements 115 or 119 and the cover 109 free spaces that have a discharge channel 123 for lateral discharge of the switching gas stream 104 from the middle arcing chamber form in opposite partial flows.

The one from the middle arcing chamber of the low-voltage circuit breaker escaping switching gas stream 104 passes through the middle inlet opening 108 in the switching gas damper 101 on. It goes directly into the through the lid 109, the Front wall 110, rear wall 111 and baffles 115 or 119 formed discharge channel 123, from which it on both Sides of the switching gas damper can escape. The hereby Partial flows of the switching gases are indicated by arrows 124 and 125 indicated.

6 shows schematically in a perspective view two further variants of an inventive Switching gas damper 101 and the flow of switching gas flows 103, 104, 105 by the same. Otherwise the same version and functionality, which is why all identical parts are not have been provided with reference numerals again, these are here used deflection elements 126 and 127 as curved or inclined straight elements educated. On another, repeated explanation of this Variants should therefore be avoided.

Through the above on the basis of several advantageous embodiments the invention explained variable arrangement of Deflection elements and discharge channels, it is possible depending of the occurring gas quantities and the properties of the used quenching chambers, several separate flow paths with different desired damping and Get cooling properties.

The described switching gas damper 1, 31, 61 and 101 can as a sheet metal or plastic body in one piece or from several Parts made together. A multi-part Structure allows multiple variants using uniform To manufacture standard parts. For example, a such a standard part having the entry openings Be the floor with the front and rear wall. Another one The standard part can be the lid. Alternatively, as Standard part is a lid with attached front and rear wall to be provided. These standard parts can be used with assemblies can be combined from the same or a different material, which the interior through channel walls and / or deflection elements divide into discharge channels.

For low-voltage circuit breakers with very high rated currents and high switching capacities is a type with two or more switching poles per phase and a corresponding number known from quenching chambers. Those belonging to a phase Extinguishing chambers then form an electrical unit. Accordingly, a discharge channel for each Arcing chambers of a switching pole are provided together, since it depends on the separation of the switching gases of the individual phases especially arrives. On the other hand, it should, for example, with consideration on the use of uniform parts, appear cheaper, to provide a discharge channel for each individual quenching chamber, this is also within the scope of the invention.

Claims (17)

1. Switching gas damper (1; 31; 61; 101) for low-voltage circuit breakers (2; 62), which is arranged as an attachment above the arcing chambers (6, 7, 8; 66, 67, 68) for additional damping, deionization and cooling of the switching gases, with the attachment having a cuboid enclosure with a front wall (10; 40; 70; 110), a rear wall (11; 41; 71; 111) and a cover (9; 39; 69; 109),
   characterized in that the cover (9; 39; 69; 109) is designed to be closed and a bottom (14; 44; 74; 114) having separate inlet openings (87; 89; 91; 107; 108) is provided for receiving switching gas flows (3-5; 33-35; 63-65; 103-105) from each arcing chamber (6, 7, 8; 66, 67, 68) in the low-voltage circuit breaker (2; 62), and in that each inlet opening (87; 89; 91; 107; 108) has an associated outlet channel (17, 21, 23; 47, 51, 53; 79, 84 86; 117, 121, 123), which is formed by channel walls (16, 20; 46, 50) and/or deflection elements (15, 19; 45, 49; 75, 76; 115. 119; 126, 127), in order to dissipate the switching gas flows (3-5; 33-35; 63-65; 103-105) at the sides.
2. Switching gas damper according to Claim 1,
   characterized in that, in a three-pole low-voltage circuit breaker (2; 62), a channel wall (20) is arranged parallel to the front wall (10) and a further channel wall (16) is arranged parallel to the rear wall (11), thus, in conjunction with deflection elements (15, 19; 45, 49), forming a total of three outlet channels (17, 21, 23), of which the outer outlet channels (17, 21), which are bounded by the front wall (19) and by the rear wall (11), are closed on opposite sides by a side wall (12 or 13 respectively), and the central outlet channel (23), which is bounded by the channel walls (16, 20), is open on both sides, such that the switching gas flows (3, 5,_\ 33, 35) which emerge from the outer arcing chambers (6, 8) of the low-voltage circuit breaker (2) are carried away separately on opposite sides, while the switching gas flow (4; 34) which emerges from the central arcing chamber (7) passes from the switching gas damper (1) to free space on both sides through the central outlet channel. (Figures 1, 2)
3. Switching gas damper according to Claim 2,
   characterized in that the channel walls (16, 20; 46, 50) extend from the bottom (14; 44) to the cover (9; 39) of the switching gas damper (1; 31), and in that the side walls (12, 13; 42, 43) are arranged on the same side of the switching gas damper (1; 31) as the outer arcing chambers (6, 8), such that the switching gas flows (3, 5; 33, 35) of the outer arcing chambers (6, 8) are passed, parallel to the front wall (10; 40) and to the rear wall (11; 41) of the switching gas damper (1; 31), to the respectively opposite side of the low-voltage circuit breaker (2), and the switching gas flow (4; 34) of the central arcing chamber (7) is passed to the two opposite sides. (Figures 1, 2)
4. Switching gas damper according to Claim 2 or 3,
   characterized in that one deflection element (15, 19; 45, 49) is in each case arranged such that it extends above the inlet openings which are associated with the outer arcing chambers (6, 8) in the bottom (14) of the switching gas damper (19) and between the channel walls (16, 20; 47, 50), and in that a side part (28; 56) is in each case arranged on the mutually facing sides of the deflection elements (15, 19; 45, 49) in order to separate the switching gas flows (3, 5) of the outer poles and the switching gas flow (4) of the central pole. (Figures 1, 2)
5. Switching gas damper according to Claim 4,
   characterized in that the first deflection element (15) extends, starting from the bottom (14) on the first channel wall (20), as far as the cover (9), and ending on the opposite channel wall (15), and the further deflection element (19) is arranged such that it rises in the opposite direction between the channel walls (16, 20), with the side parts (28) having a shape which is matched to the rising arrangement of the deflection elements (15, 19), so as to separate the switching gas flows (3, 5) of the outer arcing chambers (6, 8) and of the central arcing chamber (7). (Figure 1)
6. Switching gas damper according to Claim 4,
   characterized in that the deflection elements (45, 49) are arranged parallel to the cover (39) and to the bottom (44) above the inlet openings for guiding the switching gas flows (3, 5) of the outer arcing chambers (6, 8) and extend from one channel wall (46) to the other channel wall (50), and side parts (56) are arranged on the mutually facing sides of the deflection elements (45, 49) in order to separate the switching gas flows (3; 5) of the outer arcing chambers (6, 8) and the switching gas flow (4) of the central arcing chamber (7). (Figure 2)
7. Switching gas damper according to Claim 6,
   characterized in that the deflection elements (45, 49) are arranged at any desired height position between the cover (39) and the bottom (44) of the switching gas damper (31). (Figure 2).
8. Switching gas damper according to Claim 6,
   characterized in that the deflection elements (45, 49) are arranged at a height of 2/3 of the height of the switching gas damper (31) away from the bottom (44) of the switching gas damper (31), and are arranged parallel to the bottom (44) and to the cover (39). (Figure 2)
9. Switching gas damper according to Claim 1,
   characterized in that the deflection elements (75, 76; 115, 119; 126, 127) are at the same time in the form of channel walls and are arranged such that the switching gas flows (63, 65; 103, 105) which emerge from the arcing chambers (66, 68) of the outer poles of the low-voltage circuit breaker (62) are carried away from the switching gas damper (61; 101) directly at the sides, that is to say each on the same side of the low-voltage circuit breaker (62), and the switching gas flow (64; 104) which emerges from the central arcing chamber (67) is carried via or alongside the deflection elements (75, 76; 115, 119; 126, 127) to both opposite sides of the switching gas damper (61; 101). (Figures 3, 4, 5, 6)
10. Switching gas damper according to Claim 9,
    characterized in that the deflection elements (75, 76) are arranged such that they extend from the bottom (74) to the cover (69) of the switching gas damper (61). (Figures 3, 4)
11. Switching gas damper according to Claim 10,
    characterized in that the deflection elements (75, 76) are arranged such that, originating from the front wall (70) of the switching gas damper (61), they run between the inlet openings (87, 91 and 91, 89 respectively), which are located above the arcing chambers (66, 67, 68), in the direction of the rear wall (71), are then angled, and each run behind the inlet openings (87, 89) for the switching gases from the outer arcing chambers (66, 68) as far as the side boundary of the switching gas damper (61), in such a manner that an outlet channel (79) is formed, which is coupled to the space above the central arcing chamber (67) of the low-voltage circuit breaker (62) and is open on both sides of the switching gas damper (61), for the switching gas flow (64) of this central arcing chamber (67). (Figures 3, 4).
12. Switching gas damper according to Claim 11,
    characterized in that the angles of the deflection elements (75, 76) are rounded. (Figures 3, 4)
13. Switching gas damper according to Claim 9,
    characterized in that the deflection elements (115; 119; 126; 127) are arranged such that they extend between the front wall (110) and the rear wall (111) such that one outlet channel (117; 121) for an outer arcing chamber is in each case bounded by the bottom (114) and a deflection element (115; 119; 126; 127) and an outlet channel (123), which is open on both sides and is connected to the central inlet opening (109) in the bottom (114), is formed for the central arcing chamber between the deflection elements (115; 119; 126; 127) and the cover (109). (Figures 5, 6)
14. Switching gas damper according to one of the preceding claims,
    characterized in that a direction-changing enclosure (26) with a guide chamber (27) is attached to the side of the switching gas damper (1; 31; 61; 101), on one or both sides of the switching gas damper (1; 31; 61; loll, in order to carry the switching gas flows (3-5; 33-35; 63-65; 103-105) which emerge from the switching gas damper (1; 31; 61; 101) at the side of the low-voltage circuit breaker (2; 62) away downwards. (Figure 1)
15. Switching gas damper according to Claim 12,
    characterized in that the direction-changing enclosure (26) is angled. (Figure 1)
16. Switching gas damper according to one of the preceding claims,
    characterized in that the cover (69) of the switching gas damper (61) is lengthened beyond its side boundary, and is provided with guide elements pointing downwards.
17. Switching gas damper according to Claim 16,
    characterized in that the guide elements are formed by elongations (128), which extend downwards at the sides along the low-voltage circuit breaker (62), of the side walls (72, 73) of the switching gas damper (61). (Figure 3)

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