DE102006033954A1 - Busbar module for a gas-insulated high-voltage switchgear - Google Patents

Abstract

The invention relates to a busbar module for a gas-insulated high-voltage switchgear with a housing and with at least two phases. In the housing at least two bus bars and at least two phases are arranged. The phases of each busbar are arranged separately from each other in the housing. The busbar module according to the invention can be contained in a gas-insulated high-voltage switchgear.

Description

The The invention relates to a busbar module for a gas-insulated high-voltage switchgear according to the preambles of claims 1 and 18.

Gas insulated switchgear (GIS) are well known and have been used for decades in the nominal voltage range of about 7.2 to 800 kV. The GIS are usually executed in block technology. Plant components such as busbars, disconnectors, circuit breakers, converters, cable terminations and connecting elements are designed as gas-tight encapsulated modules. As insulating gas usually sulfur hexafluoride (SF ₆ ) is used, but other gases are used.

busbars are for designed the power distribution in panels with phase conductors and in particular as distribution modules to various functional modules, such as power or disconnect switches used. For three-phase Switchgears are the individual phase conductors (L1, L2, L3) within a module usually arranged parallel to each other. Is there a need? a switching field with several phase conductors per phase, one sets several busbars, for example as double busbars, which are composed of the aforementioned modules. conventional Gas-insulated switchgear operates with a spring-loaded drive for the Circuit breaker and a motorized drive for the circuit breaker.

outgoing From this prior art, it is the object of the invention Busbar module for to provide a gas-insulated high-voltage switchgear and such which has a compact design and a compact Arrangement of gas-insulated switchgear leads.

These Task is solved by a busbar module for a gas-insulated high-voltage switchgear with the in claim 1 mentioned features.

Accordingly, FIG the busbar module according to the invention of the type mentioned a housing, in which at least two bus bars, each with the at least two phases arranged in the housing are and that the corresponding phases of each busbar are arranged separately from each other electrically.

One The advantage of this arrangement is that only one housing for multiple busbars in a gas-insulated high-voltage switchgear is necessary.

This guaranteed a cheaper production the switchgear and a comparatively compact arrangement. So For example, when needing a triple busbar only another case needed instead of three busbar modules as before. Also a comparatively favorable Assembly of the busbar module according to the invention is thereby made possible.

A advantageous embodiment of the busbar module is that the case at least two separate gas rooms having.

Preferably are in the respective gas chambers arranged the busbars. Later maintenance work on a busbar a special are possible. In addition, there is only one left Mounting for mounting for individual sections of the busbar module necessary.

A Another embodiment of the subject invention provides that a separating element is arranged, preferably as a straight dividing wall is formed and positioned approximately centrally between the busbars is.

so shows the case at least two housing parts on and that by the at least two housing parts a gas-tight gas space is trained.

A Maintenance of one of the at least two busbars is then without one Shutdown of an electrical system allows, with a current flow over at least one of the at least two busbars. Only one in maintenance located busbar is switched off.

When favorable Training the busbar module is proposed that the Housing at least two housing parts has, that through the at least two housing parts, a gas-tight gas space is formed and that the housing parts with Connecting elements, in particular with webs, are connected and / or welded are. This will increase the stability of the module opposite increased mechanical stress.

A sees further advantageous embodiment of the busbar module before that the case a common connection flange on at least one connection side of the housing for the least has two busbars.

In this way, the manufacturing costs are reduced and in the assembly of the module comparatively little time is taken. The space requirement for two or more connection flanges on a busbar module is made possible by the use of a single on end flange for a module also reduced. It can be realized a more compact design of the busbar module and the switchgear.

A greater flexibility in the Use of the busbar module according to the invention is advantageously achieved in that the housing each have a connection flange at least one connection side of the housing in each case one of the at least has two busbars and / or that the housing for each the at least two phase conductors on at least one connection side has a connection flange.

A Maintenance or installation of the individual connections is facilitated. The order a connecting flange per busbar also serves as a connecting element to another high-voltage switchgear module, for example in a busbar module known since then.

Also according to the invention a branch of the phase conductors to and / or from outside the busbar module possible, in which an additional Connection flange on the housing is attached and a branch of the respective busbar led to becomes.

By arranging a plurality of connection flanges to the housing a separate connection possibility for further Modules realized. A change from three-phase modules to single-phase is particularly easy.

A sees further advantageous embodiment of the busbar module before that in the case at least a converter per phase and / or a converter per phase conductor one Busbar is arranged, preferably in the vicinity of a connection flange.

A Measurement of currents and voltages in the area of the busbars or phase conductors according to the invention without additional space realizable.

A Further development of the busbar module according to the invention provides that each of the at least two busbars is three-phase is formed such that the phase conductors of each busbar as a cross-sectional view to its longitudinal extent form the vertices of an imaginary triangle, and that ones Sides of the imaginary triangles are arranged in parallel, which the have the least distance from each other, with the imaginary triangles spaced apart from each other.

Of the Distance between the two imaginary triangles is essentially freely selectable, provided a minimum distance corresponding to the occurring voltage and relevant Regulations is complied with.

The Busbars with their phase conductors can be particularly space-saving in a correspondingly preferred housing with an oval cross-section be arranged, with the necessary distances of the housing to the phase conductors to consider are. Very cheap it is when the phase conductors of the bus bars of the same phase lie next to each other. The distance between the busbars to each other is thereby considerably reduced. The busbar module has a compact design has a correspondingly small footprint.

A Another advantageous embodiment is achieved when in three-phase Operation in the housing the Phase conductor per busbar in cross section to the longitudinal extent forming a thought triangle and the furthest away Sides of the imaginary triangle are parallel to each other, the imaginary triangles are spaced from each other. Here too may one the phase conductor spacing a minimum distance because of the occurring voltage do not fall short. In the educated spaces between the imaginary ones mutually facing triangular peaks and the substantially thereof Lateral area is a space, especially for arrangement various equipment, such as disconnector switch, earthing switch, Circuit breaker or similar.

A Another advantageous embodiment provides that the busbar module at least one disconnector and / or at least one circuit breaker having. The space required for the busbar module according to the invention is thus even lower compared to the space requirements of the modules since then known HV systems.

Further Advantages are achieved when the at least one separator and / or at least one circuit breaker by a drive, in particular a sequential drive, can be acted upon and that a drive with at least two of the devices disconnectors and / or circuit breaker cooperates.

Conventional disconnectors and circuit breakers are each acted upon by a drive associated therewith, wherein a combination of isolator and earthing switch can also be acted upon by a drive. With a common drive for at least two of the devices further space savings is guaranteed. The sequential drive is designed to switch in a predetermined but selectable order between the individual Devices and is for the life and safety of the switching devices and / or the module and / or the gas-insulated switchgear of importance.

A Training of the subject invention provides that the circuit breaker and / or the earth electrode and / or the transducer and / or the separator in the Gas room or separately in other rooms are arranged.

The Arranging the devices in the busbar module further reduces the space required accordingly. The devices can be arranged in a space-optimized way.

The Task is also solved with a high-voltage switchgear with the features according to claim 18th

A Compact system is already through the use of a busbar module according to the invention reached.

by virtue of the particularly space-saving construction of the module can be realize a compact gas-insulated high-voltage switchgear and the assembly time can be reduced accordingly.

there it has to be cheap Training of the switchgear proved that at least two Switchgear, in particular circuit breakers and / or earthing and / or disconnectors, can be acted upon by a common drive. The space requirement for many Drives is accordingly by replaced the space requirement of only one drive.

The Switchgear is particularly compact, cost-effective and easy to install produced.

As well is a switchgear such that the drive from / to a busbar-foreign module is arranged.

From the common drive of the busbar module foreign, the drive required functions of the busbar module can be acted upon. The space for the respective drive on the busbar module is eliminated. Again, a comparatively compact arrangement of the switchgear is realized,
and it is possible to realize a more compact module or a more compact switchgear.

The same applies to the forwarding of the drive of the above busbar module to another module.

Based of the drawings, in which three embodiments of the invention are shown, the invention and advantageous embodiments of the Invention closer explained with reference to schematic and not to scale figures and to be discribed.

It demonstrate:

1 : Switchgear with a first busbar module with a double busbar

2 : Scheme of an assignment of several switching devices to a drive

3 : Sectional view through a second busbar module

4a -C: Cross sections through several busbar modules

5 : Arrangement of a switchgear

1 shows an embodiment of a first gas-insulated high-voltage switchgear (GIS) 18 , which usually includes cable feeders, circuit breakers, busbar modules, circuit breakers, converters and other equipment. In the illustration, for the sake of clarity, only the GIS 18 with a first busbar module according to the invention 1 contain. At a first housing 26 of the first busbar module 1 are four connection flanges, a first connection flange 13 , a second connection flange 14 , a third connection flange 23 and a fourth connection flange 24 shown. These four connection flanges 13 . 14 . 23 . 24 make the possibility of connecting a first busbar 2 and a second busbar 3 to other external modules, such as connecting cables or other devices, which are not shown in this figure, or also first external current transformer 21 or second external current transformer 22 , The first 13 and second connection flange, 14 act as incoming connection flanges of the first connection side 85 , the third 23 and fourth connection flange 24 as outlet side flanges on the second connection side 86 , The connecting flanges are at the first 2 and second busbar 3 and are thus the input and output side of the first busbar module 1 arranged. The first external current transformer 21 serves to measure the current of its associated first busbar 2 while the second external current transformer 22 the current of the second busbar 3 measures. The first 21 and second external current transformers 22 are in modular design the third and fourth connection flange 23 . 24 affiliated. The first 21 and second external current transformers 22 are designed to be accessible from the outside and can be easily removed for example for maintenance tasks.

Furthermore, on the outside of the first housing 26 a first drive 15 arranged. The functional connection of the first drive 15 with other equipment, such as isolator switch or circuit breaker, is included 2 described in more detail. The first case 26 has a first gas-insulated room 25 with the insulating gas sulfur hexafluoride (SF ₆ ) which serves as a switching and insulating agent. In the selected example, this is a switchgear with 72.5 kV maximum rated voltage, a nominal current of 2500 A and a nominal breaking current of 315 kA. In the first gas-insulated room 25 are the first 2 and second busbar 3 arranged, which form a double busbar. Every first 2 and second busbar 3 contains in three-phase operation three phase conductors for transmitting an alternating current of different phase, usually with the names L1, L2, L3. Each of the phase conductors is on the output side of the first busbar module 1 a first circuit breaker 10 assigned and is in the embodiment in the first case 26 of the first busbar module 1 arranged. The first circuit breaker 10 is designed for switching under load. On the input side, each of the phase conductors is the first one 2 and second busbar 3 a first isolator / ground combination switch 11 assigned. This first isolator / earth combination switch 11 consists essentially of a first isolator switch 16 and a first earthing switch 17 , The first disconnector switch 16 is such that only switching without load can be performed and is usually used for secure shutdown.

The first earthing switch 17 is intended for grounding the busbar module. Usually, the first isolator / ground combination switch 11 three switching combinations, namely "on", "off" and "earthed" and serves the earth in a de-energized state 5 explained in more detail. For safety reasons, to disconnect an electrical system from the grid at the first busbar module 1 but usually first, the first circuit breaker 10 switched to "off".

2 shows a diagram of the relationships between the drive and the resources. The dash-dot line represents the system boundary of the second busbar module 40 Is by a second drive 36 the second busbar module 40 switched off, so first the second circuit breaker 37 placed on his position "off" and thus opened (cf. 1 and 5 ). This is by a first arrow 29 shown. Only when the second circuit breaker 37 is fully open (by a second arrow 30 shown) the second disconnector switch 38 through the second drive 36 open, indicating third arrow 31 is shown. The second drive 36 then controls, by a fourth arrow 32 illustrates the second earth electrode 39 (with fifth arrow 33 shown).

How to turn on an electrical system is described below with reference to 1 described. First, the second earthing switch 39 with the help of the second drive 36 opened (fifth arrow 33 ) and thus the busbar separated from ground potential. After that (sixth arrow 34 ) becomes the second disconnector switch 38 through the second drive 36 charged (third arrow 31 ). Only if the second disconnector switch 38 closed (seventh arrow 35 ) is an operation of the second circuit breaker 37 possible. The second drive 36 closes the second circuit breaker 37 and the output-side electrical system is thus "under voltage." In order to disconnect the electrical system from the grid, the above-described working steps are carried out in the reverse order.

To be able to comply with these orders and thus effect a mutual lock, is for the second drive 36 used a sequential drive. In this way, the above-mentioned releases or interlocks between the second circuit breaker 37 and the second disconnector switch 38 and between the second disconnector switch 38 and the second earthing switch 39 realized in a simple way, while the second drive 36 the three switching devices 37 . 38 and 39 acted upon in the predetermined time sequence.

3 shows a representation of a third busbar module 41 with a double busbar as a side view on the Längsersteckung with a third busbar 42 and a fourth busbar 43 , On a second housing 46 are a common connection flange 12 on the one hand and two connecting flanges, a fifth connecting flange 44 for the third busbar 42 and a sixth connection flange 45 for the fourth busbar 43 arranged on the other hand. The common connection flange 12 is the third 42 and the fourth busbar 43 arranged. Through the second housing 46 becomes a second gas-insulated room 47 limited, in which the third 42 and fourth busbar 43 are arranged.

At the fifth 44 or the sixth connection flange 45 For example, single busbar modules with only one busbar can be arranged while the common connection flange 12 with another busbar module with at least one common connection flange 12 is connectable. With the fifth 44 , the sixth connection flange 45 or the common connection flange 12 are also switching devices like For example, circuit breaker, disconnector switch, earth, disconnector / earthing combination switch or other resources such as converters for voltage and current measurement / determination or other equipment parts of a switchgear connectable.

With the above construction of the third bus bar module 41 Busbar modules with several busbars are conceivable for the person skilled in the art. Instead of a common connection flange 12 It is also possible to use other customary, for example single- or three-phase connection flanges.

The 4a to c show different cross-sections to the longitudinal extent of double busbars of a busbar module according to the invention, wherein in particular various possibilities of arranging the phase conductor will be discussed.

It is in 4a an oval in this view third housing 51 a first double busbar module 48 shown. In the first double busbar module 48 is a double busbar with a fifth busbar 49 with the associated phase conductors, namely a first phase conductor 4 , a second phase conductor 5 and a third phase conductor 6 and a sixth busbar 50 with a fourth phase conductor 7 , a fifth phase conductor 8th and a sixth phase conductor 9 , For clarity, around the fifth busbar 49 and the sixth busbar 50 Areas drawn with dotted lines. The first phase conductor 4 , the second phase conductor 5 and the third phase conductor 6 the fifth busbar 49 form a thought first triangle 52 and the fourth phase conductor 7 , the fifth phase conductor 8th and the sixth phase conductor 9 the sixth busbar 50 form a thought second thought triangle 53 , where the triangles 52 . 53 are designed equilateral. The side of the first imaginary triangle 52 that the second triangle 53 is closest, run parallel. The two phase conductors of the same phase position are preferably closest to each other. A first distance d1 of the triangles to each other in this case is the spacing of the phase conductors with the respective same phase, for example between the first phase conductor 4 with the conventional designation L1 and the fourth phase conductor 7 with the same phase position or the second phase conductor 5 with the conventional name 12 and the fifth phase conductor 8th same phase position.

The distance d1 is only the respective safety distance for the simple phase voltage, since maximum between the first phase conductor 4 and the fourth phase conductor 7 the only simple phase voltage can occur. Would be the first phase conductor 4 and second phase conductor 7 different phase position, the first distance d1 would have to be calculated according to the outer conductor voltage. The phase conductors 4 to 9 are taking into account the distance rules space optimized in the third housing 51 to arrange.

4b shows a second arrangement of phase conductors in a second double busbar module 54 , The assignment of a seventh phase conductor 55 , an eighth phase conductor 56 and a ninth phase conductor 57 to a seventh busbars 58 is characterized as in the figure previously with a dash-dotted line. The same applies to the area of the eighth busbar 59 with the tenth phase conductor 60 , eleventh phase conductor 61 and twelfth phase conductor 62 drawn. Both the seventh phase conductor 55 , the eighth phase conductor 56 and the ninth phase conductor 57 as well as the tenth phase conductor 60 , the eleventh phase conductor 61 and the twelfth phase conductor 62 each form the vertices of a third imaginary triangle 63 and the vertices of a fourth imaginary triangle 64 , The furthest apart sides of the third imaginary triangle 63 and the fourth imaginary triangle 64 are located here parallel to each other.

The thus pointing to each other tip of the triangles and at the actuator of their smallest distance d2 of the seventh busbar 58 to the eighth busbar 59 namely the eighth phase conductor 56 and the eleventh phase conductor 61 , are in the same phase position.

The advantage is, as well as in 4a described that only a relatively smaller second distance d2 of the third triangle to the fourth triangle according to relevant safety regulations is necessary.

In 4c is another way to arrange phase conductors in a third double busbar module 65 shown. The fourth case 66 of the third double busbar module 65 circumscribes a third enclosed by the housing interior 67 , The third enclosure enclosed by the housing 67 is in two separate gas rooms, a first gas room 27 and a second gas space 28 split, which is indicated by a dash-dot line. In the first gas room 27 is a ninth busbar 68 with a thirteenth phase conductor 69 , a fourteenth phase conductor 70 and a fifteenth phase conductor 71 arranged. in the second gas space 28 is a tenth busbar 72 with a sixteenth phase conductor 73 , with a seventeenth phase conductor 74 and with an eighteenth phase conductor 75 arranged. The phase conductors per busbar are in a line parallel to the dash-dot line assigns. The distance d3 between the phase conductors of the ninth busbar 68 and the tenth busbar 72 the same phase position is chosen to be minimal according to the simple phase conductor spacing.

Of the third distance d3 can because of the simple phase voltage gap correspondingly at each phase with the comparatively small distance d2 be set. this leads to to a busbar housing, which looks particularly flat in this view.

The in the 4a to c illustrated ways of arranging the phase conductors in a double busbar module can be applied accordingly for busbar modules with multiple busbars.

So is for example at five Busbars in three-phase operation with respect to

4a an arrangement is possible in which the busbars form five triangles and, viewed as a whole, form the shape of a pentagon. Further busbars can be realized in a circular arrangement in a busbar module.

Also Arrangements on an asymmetric basis can be realized. Depending on Default for a housing can various models are built.

In 5 is another embodiment of a fourth busbar module 76 listed. It is a fifth case 77 of the fourth busbar module 76 shown in which fifth housing 77 two busbars in parallel, namely an eleventh busbar 78 and a twelfth busbar 79 are arranged, with the eleventh busbar 78 the input side represents the twelfth busbar 79 the output side. Each of the busbars has at least two, but the same number of phase conductors, which are not shown for clarity. The entrance of the eleventh busbar 78 forms a ninth connection flange 84 , the departure of the twelfth busbar 79 a tenth connection flange 85 , In the fourth busbar module 76 are at the eleventh busbar 78 On the input side, a first internal current transformer 19 and at the twelfth busbars 79 on the output side, a second internal current transformer 20 appropriate. The first 19 and the second internal current transformer 20 are in one of the fifth case 77 formed third gas-insulated space arranged.

On the twelfth busbar 79 is a third circuit breaker 80 designed for switching an electrical system. With the fourth busbar module 76 is a second disconnector / earthing combination switch 81 as a separate module via a seventh connection flange 82 and an eighth flange 83 connected. The seventh connection flange 82 is at the exit of the eleventh busbar 78 , the eighth flange 83 is at the entrance of the twelfth busbar 79 arranged.

5 shows the fourth busbar module 76 in the switched-off operating state. The operating situation of the fourth busbar module 76 is chosen so that a current flow on the input side via a ninth connection flange 84 , the eleventh busbar 78 and the first internal current transformer 19 into the fourth busbar module 76 flows. The electricity is from the eleventh busbar 78 over the seventh connection flange 82 back from the eleventh busbar 78 led out to the outside. This is a module with a second isolator / earthing combination switch 81 connected, so that the flow of current through this second isolator / earth combination switch 81 flows. From this second disconnector / earthing combination switch 81 is by an electrical connection via an eighth flange 83 with the twelfth busbar 79 of the busbar module 1 created. From there, the current flows through the third circuit breaker 80 and the second internal current transformer 20 the twelfth busbar 79 , The electricity is from the twelfth busbar 79 to a tenth connection flange 85 and is thus provided for further use in other modules.

A connection to the network of the fourth busbar module 76 (see. 2 ) can be carried out as follows:
The initial situation is that the second isolator / earthing combination switch 81 has a switching position to ground, which is referred to as the end position. To switch on, first the disconnector / earthing combination switch 81 brought to a middle position. Once the center position (or neutral position) of the second isolator / earth combination switch 81 is reached, the second isolator / earth combination switch 81 connected by a drive so that an electrically conductive connection between the eleventh busbar 78 and the twelfth busbar 79 is made. Once this is done, the third circuit breaker becomes 80 acted upon by the drive. After performing this step, the electrical system connected on the output side is switched to the mains.

Switching off the system and thus disconnecting the electrical system from the grid by opening the fourth circuit breaker 76 , In the on The reason for this is the second isolator / earthing combination switch 81 acted upon so that this is initially in a middle position ("off") and the twelfth busbar 79 disconnects from the grid. Subsequently, the twelfth busbar 79 via a further admission of the second isolator / earthing combination switch 81 in an "earth position" and thus the potential of the twelfth busbar 79 if there are any currents, they are conducted to earth potential.

1

first Busbar module

2

First bus

3

Second bus

4

first phase conductor

5

second phase conductor

6

third phase conductor

7

fourth phase conductor

8th

Fifth phase conductor

9

six phase conductor

10

first breakers

11

first Disconnector / earthing combination

12

common flange

13

first flange

14

second flange

15

first drive

16

first isolator switch

17

first Erderschalter

18

gas Insulated High-voltage switchgear

19

first internal current transformer

20

second internal current transformer

21

first external current transformer

22

second external current transformer

23

third flange

24

fourth flange

25

first gas-insulated room

26

first casing

27

first headspace

28

second headspace

29

first arrow

30

second arrow

31

third arrow

32

fourth arrow

33

Fifth arrow

34

six arrow

35

seventh arrow

36

second drive

37

second breakers

38

second isolator switch

39

second Erderschalter

40

second Busbar module

41

third Busbar module

42

third bus

43

Fourth bus

44

Fifth connection flange

45

six flange

46

second casing

47

second gas-insulated room

48

first Double busbar module

49

Fifth busbar

50

Sixth bus

51

third casing

52

first triangle

53

second triangle

54

second Double busbar module

55

seventh phase conductor

56

eight phase conductor

57

ninth phase conductor

58

Seventh bus

59

Eighth bus

60

tenth phase conductor

61

eleventh phase conductor

62

Twelfth phase conductor

63

third triangle

64

fourth triangle

65

third Double busbar module

66

fourth casing

67

third from the case enclosed interior

68

Ninth bus

69

Thirteenth phase conductor

70

Fourteenth phase conductor

71

Fifteenth phase conductor

72

Tenth bus

73

sixteenth phase conductor

74

Seventeenth phase conductor

75

Eighteenth phase conductor

76

fourth Busbar module

77

Fifth housing

78

Eleventh bus

79

Twelfth busbar

80

third breakers

81

second Disconnector / earthing switch combination

82

seventh flange

83

eight flange

84

ninth flange

85

tenth flange

86

First terminal side

87

Second terminal side

d1

first distance

d2

second distance

d3

third distance

Claims (20)

Busbar module for a gas-insulated high-voltage switchgear, with a housing and at least two phases, characterized in that at least two bus bars, each having the at least two phases are arranged in the housing and that the corresponding phases of each busbar are arranged separately from each other electrically. Busbar module according to claim 1, characterized characterized in that the housing at least two separate gas rooms having. Busbar module according to claim 1 or 2, characterized characterized in that the housing at least two housing parts and that by the at least two housing parts a gas-tight gas space is trained. Busbar module according to Claim 3, characterized that the housing parts with connecting elements, in particular with webs, are connected and / or welded are. Busbar module according to one of the preceding claims, characterized characterized in that the housing at least one common connection flange on at least one Connection side of the housing for the has at least two busbars. Busbar module according to one of the preceding claims characterized characterized in that the housing one connection flange each for each of the at least two busbars on at least one terminal side having. Busbar module according to one of the preceding claims characterized characterized in that the housing a connection flange for each of the at least two phase conductors on at least one connection side having. Busbar module according to one of the preceding claims, characterized characterized in that in the housing at least one converter per phase and / or one converter per phase conductor a busbar is arranged, preferably in the vicinity of a connecting flange. Busbar module according to one of the preceding claims, characterized in that each of the at least two busbars has a three-phase design is that the phase conductors of each busbar as a cross-sectional view to its longitudinal extent form the vertices of an imaginary triangle, and that ones Sides of the imaginary triangles are arranged in parallel, which the have the least distance from each other, with the imaginary triangles spaced apart from each other. Busbar module according to one of claims 1 to 8, characterized in that in three-phase operation in the housing the Phase conductor per busbar in cross section to the longitudinal extent forming a thought triangle and the furthest away Sides of the imaginary triangle are parallel to each other, the imaginary triangles are spaced from each other. Busbar module according to one of claims 1 to 8, characterized in that in three-phase operation in the housing the Phase conductor in cross section to the longitudinal extent of each busbar Located on a thought straight line and the lines to each other are parallel. Busbar module according to one of the preceding claims, characterized characterized in that the housing in cross-section to its longitudinal extent has a roughly oval Gestallt. Busbar module according to one of the preceding claims, characterized characterized in that the busbar module at least one disconnector and / or has at least one circuit breaker. Busbar module according to Claim 13, characterized that the at least one disconnector and / or at least one circuit breaker a drive, in particular a sequential drive, acted upon is. Busbar module according to claim 13 or 14, characterized characterized in that a drive with at least two of the devices separator and / or circuit breaker cooperates. Busbar module according to one of the preceding claims, characterized in that the circuit breaker and / or the earth electrode and / or the converter and / or the separator in the gas space or separately in another clear are arranged. Busbar module according to one of the preceding claims, characterized characterized in that at least one of the busbars a branch and an associated one Departure on the housing having. Gas-insulated high-voltage switchgear, thereby in that a busbar module according to one of the aforementioned claims is included. Gas-insulated high-voltage switchgear according to claim 18, characterized in that at least two switching devices, in particular Circuit breaker and / or earth electrode and / or disconnectors, which are in different Modules are arranged, acted upon by a common drive are. Gas-insulated high-voltage switchgear according to claim 18 or 19, characterized in that the drive from / to a busbar-foreign module is arranged.