DE29816914U1 - Gas-insulated switchgear with three-phase encapsulated busbar and single-phase encapsulated circuit breakers - Google Patents

Description

GR 98 G 4171 EN

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Description

Gas-insulated switchgear with three-phase encapsulated busbar and single-phase encapsulated circuit breakers

The invention relates to a gas-insulated switchgear with a three-phase encapsulated busbar and single-pole encapsulated circuit breakers, in which the current paths of the circuit breakers can be connected to or separated from the phase conductors of the busbar accommodated in an encapsulation housing via combined isolator/earthing switches, wherein the drivable contacts of the combined isolator/earthing switches can be actuated by a drive arranged outside the encapsulation housing.

In gas-insulated switchgear with a three-phase encapsulated busbar and single-pole encapsulated circuit breakers, the three phase conductors of the busbar of a switch panel run essentially parallel to one another within the gas space of an encapsulation housing, which is closed off at its front ends by bulkhead insulators. While the single-pole encapsulated circuit breakers assigned to the three phase conductors of the busbar are arranged outside the encapsulation housing of the busbar and are flanged to it, it is generally known that the isolating switches also assigned to the three phase conductors of the busbar, which can also be designed as combined isolating/earthing switches and via which the current paths of the circuit breakers can be connected to or separated from the three phase conductors of the busbar, are arranged essentially inside this encapsulation housing. The drive for actuating the drivable contacts of the isolating switches is, however, located outside the encapsulation housing that accommodates the three phase conductors of the busbar.

GR 98 G 4171 EN

In such gas-insulated switchgear, the single-pole encapsulated circuit breakers and the disconnectors arranged within the gas space of the encapsulation housing have the same pole pitch, so that a single-pole encapsulated circuit breaker and a disconnector associated with one of the three phase conductors of the busbar are always arranged in alignment with each other. This pole pitch therefore determines the dimensions of the encapsulation housing and thus of the associated switch panel, as well as the size of the drive rods and the drive heads of the disconnectors.

Starting from a gas-insulated switchgear with the features of the preamble of claim 1, the invention is based on the object of reducing the space requirement for the encapsulation housing accommodating the phase conductors of the busbar and for the drive system of the combined isolator/earthing switch.

This task is solved by making the pole pitch of the three combined isolator/earthing switches smaller than the pole pitch of the three single-pole encapsulated circuit breakers.

According to a preferred embodiment, the middle of the three combined isolator/earthing switches and the middle of the three single-pole encapsulated circuit breakers can be arranged in alignment with one another. In this case, the two external combined isolator/earthing switches, whose drivable contacts can be actuated in the axial direction and are designed as sliding contacts, have a smaller distance from the combined isolator/earthing switch arranged in the middle than the two external circuit breakers have from the circuit breaker arranged in the middle.

By reducing the pole pitch of the combined isolator/earthing switch, there is more space in the area of the connection flanges of the

GR 98 G 4171 EN

The encapsulation housing that accommodates the busbar provides more space for assembly purposes. The additional space available also enables the drive of the combined isolator/earthing switch, which is located directly on the outer circumference of the encapsulation housing, to be compactly assigned to the drive heads of these switches, thus reducing the effort required for the drive rods.

In order to facilitate the arrangement of the contact systems of the combined isolator/earthing switch within the encapsulating housing, in a further embodiment of the invention the three phase conductors of the busbar within the encapsulating housing are cranked in the switching-on direction of the sliding contacts of the combined isolator/earthing switch to form a free space and in the area adjacent to the cranks each have a fixed inlet contact for the sliding contact of the associated isolator/earthing switch.

According to a further feature of the invention, in the free space within the encapsulation housing formed by the offset of the three phase conductors of the busbar, a fixed through-contact is arranged in alignment with each fixed inlet contact, also for the sliding contacts of the combined isolator/earthing switch. Each through-contact is galvanically connected to the current path of the associated circuit breaker and can be attached to the encapsulation housing via a support insulator, for example.

While the through-contacts are galvanically connected to the fixed inlet contacts via the sliding contacts of the combined isolator/earthing switch in the "on position", after reaching the "off position" they are galvanically connected to earthing contacts provided in the wall of the encapsulating housing and designed as through-contacts.

GR 98 G 4171 EN

In order to achieve the resulting functions without mutual interference, the sliding contacts of the combined isolator/earthing switch are made of a contact material over a length that is necessary in the "on" position to transfer current from the through contacts to the inlet contacts. The sliding contacts are supported by switching rods made of insulating material that are connected to the drive via a deflection gear.

In order to create the same conditions for each of the three combined isolator/earthing switches during switching operations, both the inlet contacts assigned to the three phase conductors of the busbar and the through contacts assigned to the circuit breakers are each arranged on a plane running in the axial direction of the encapsulating housing. This means that the drivable contacts of the combined isolator/earthing switches, designed as sliding contacts, together with the switching rods, have the same length despite the height-staggered arrangement of the three phase conductors of the busbar within the encapsulating housing.

The effects intended by the invention are also achieved if only isolating switches are used instead of the combined isolating/earthing switches. 25

The invention is explained in more detail using an embodiment.

The accompanying drawings show:

Figure 1 is a schematic representation of the different pole pitch of single-pole encapsulated circuit breakers and combined isolator/earthing switches in a three-phase encapsulated busbar of a gas-insulated switchgear and

GR 98 G 4171 EN

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Figure 2 shows a longitudinal section of an encapsulation housing according to

Figure 1 with a busbar consisting of three phase conductors and three combined isolator/earthing switches.
5

As Figure 1 shows, in a three-phase encapsulated busbar of a gas-insulated switchgear, the three phase conductors 5, 6, 7 of a busbar, which run essentially parallel to one another, are arranged within the gas space 1 of an encapsulation housing 2. While the encapsulation housing 2 can be connected to system components not shown in more detail via bulkhead insulators 3, 4 arranged on the front sides, three single-pole encapsulated circuit breakers 8, 9, 10 are flanged to the encapsulation housing 2, the current paths 11, 12, 13 of which are separated from the phase conductors 5, 6, 7 of the busbar by the isolator/earthing switches 14, 15, 16 arranged essentially within the gas space 1 after a switching-off process carried out by the circuit breakers 8, 9, 10.

While the structural design of this separation is evident from Figure 2, in Figure 1 the isolator/earthing switches 14,15,16 are only shown symbolically with regard to the separation of the current paths 11,12,13 from the phase conductors 5,6,7. Therefore, Figure 1 essentially shows the different pole pitches of the circuit breakers 8,9,10 and the isolator/earthing switches 14,15,16 and the resulting space-saving arrangement of the drive 17 of the isolator/earthing switches 14,15,16, but also the resulting space gain on the front sides of the encapsulation housing 2 in the area of the bulkhead insulators 3,4 for the coupling with encapsulation housings of other system components. Based on this, it can be seen from Figure 1 that the pole pitch P _T of the combined isolator/earthing switches 14,15,16 is smaller than the pole pitch P _L of the circuit breakers 8,9,10. The one in the middle

GR 98 G 4171 EN

The combined isolating/earthing switch 15 and the circuit breaker 9 arranged in the middle are arranged in alignment with one another, so that, taking into account the smaller pole pitch P _T of the combined isolating/earthing switch 14, 15, 16, there is sufficient space both for the arrangement of the drive 17 - the drive rod 18 of which is connected to the switching rods 25, 26, 27 via deflection gears 22, 23, 24 provided in the drive heads 19, 20, 21 - and for the coupling of the encapsulation housing 2 with other encapsulation housings. It is therefore not necessary to increase the enclosed space of the encapsulation housing 2. As the phase conductors 5, 6, 7 of the busbar are bent within the encapsulation housing 2, a free space 2 8 is formed in the gas space 1 of the encapsulation housing 2, which serves to accommodate the combined isolator/earthing switches 14, 15, 16, so that they are arranged in a space-saving manner within the encapsulation housing 2, taking into account a sufficiently high dielectric strength.

The encapsulation housing 2 shown in Figure 2 accommodates the three phase conductors 5, 6, 7 in its gas chamber 1, which are arranged offset in height from one another, run essentially parallel to one another and are bent to form the free space 28. While the gas chamber 1 is closed on one end by a bulkhead insulator 4 assigned to the encapsulation housing 2, the gas chamber 1 is closed on the other end by the bulkhead insulator of an adjoining system component (not shown in more detail). The free space 28 formed by the offsets 29, 30 in the gas chamber 1 is essentially used to accommodate the contact system of the 3 combined isolator/earthing switches 14, 15, 16 in a space-saving manner and with a sufficiently high dielectric strength. The pole pitch P _T of this contact system and thus of the combined isolator/earthing switches 14, 15, 16 is smaller than the

GR 98 G 4171 EN

Pole pitch P _L of the single-pole encapsulated circuit breakers 8,9,10 - Figure 1 -, which are connected to the encapsulation housing 2 via the flanges 31,32,33.

The contact system of the three combined isolator/earthing switches 14, 15, 16, of which the combined isolator/earthing switch 15 arranged in the middle is aligned with the circuit breaker 9 arranged in the middle - Figure 1 -, consists of the fixed inlet contacts 34, 35, 36, which are galvanically connected to the phase conductors 5, 6, 7, for the drivable contacts 37, 38, 39 designed as sliding contacts, the fixed through contacts 40, 41, 42, each of which is galvanically connected to the current path 11, 12, 13 of the associated circuit breaker 8, 9, 10 - Figure 1 -, and the earthing contacts 44, 45, 46, which are provided in the wall 4 3 of the encapsulating housing 2 and are also designed as through contacts. In this case, both the inlet contacts 34, 35, 36 and the through-contacts 40, 41, 42 are each arranged on a plane running in the axial direction of the encapsulation housing 2, so that the sliding contacts 37, 38, 39 together with the switching rods 25, 26, 27, which are connected to the drive 17 via the deflection gears and drive rods shown in Figure 1, have the same length despite the height-staggered arrangement of the three phase conductors 5, 6, 7 of the busbar.

In Figure 2, the sliding contacts 37,38,39 of the combined isolator/earthing switches 14,15,16 are shown in the "off position". The through-contacts 40,41,42 and thus the current paths 11,12,13 of the circuit breakers 8,9,10 - Figure 1 - are galvanically connected to the earthing contacts 44,45,46 via the sliding contacts 37,38,39, so that after the separation process, which was initiated by the sliding contacts 37,38,39 running out of the inlet contacts 34,35,36, the sliding contacts 37,38,39 in the "off position" simultaneously

GR 98 G 4171 EN

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"Earthed position". To enable this function, the sliding contacts 37,38,39, which are carried by switching rods 25,26,27 made of insulating material, are made of a contact material over a length which, in the "setting" for current transmission from the through contacts
40,41,42 to the inlet contacts 34,35,36 is required.

Claims (7)

1. Gas-insulated switchgear with a three-phase encapsulated busbar and single-pole encapsulated circuit breakers, in which the current paths of the circuit breakers can be connected to or separated from the phase conductors of the busbar accommodated in an encapsulation housing via combined isolator/earthing switches, wherein the drivable contacts of the combined isolator/earthing switches can be actuated by a drive arranged outside the encapsulation housing, characterized in that the pole pitch (P _T ) of the three combined isolator/earthing switches ( 14 , 15 , 16 ) is smaller than the pole pitch (P _L ) of the three single-pole encapsulated circuit breakers ( 8 , 9 , 10 ). 2. Gas-insulated switchgear according to claim 1, characterized in that the middle ( 15 ) of the three combined isolator/earthing switches ( 14 , 15 , 16 ) and the middle ( 9 ) of the three single-pole encapsulated circuit breakers ( 8 , 9 , 10 ) are arranged in alignment with one another. 3. Gas-insulated switchgear according to claim 2, characterized in that the drivable contacts ( 37 , 38 , 39 ) of the combined isolator/earthing switches ( 14 , 15 , 16 ) are sliding contacts. 4. Gas-insulated switchgear according to claim 3, characterized in that the three phase conductors ( 5 , 6 , 7 ) of the busbar are cranked within the encapsulation housing ( 2 ) in the switching-on direction of the sliding contacts ( 37 , 38 , 39 ) to form a free space ( 28 ) and in the region adjoining the cranks ( 29 , 30 ) each have a fixed inlet contact ( 34 , 35 , 36 ) for the sliding contacts ( 37 , 38 , 39 ). 5. Gas-insulated switchgear according to claim 4, characterized in that a fixed through-contact ( 40 , 41 , 42 ) for the sliding contacts ( 37 , 38 , 39 ) is arranged within the free space ( 28 ) in alignment with each fixed inlet contact ( 34 , 35 , 36 ), each through-contact ( 40 , 41 , 42 ) being galvanically connected to the current path ( 11 , 12 , 13 ) of the associated circuit breaker ( 8 , 9 , 10 ). 6. Gas-insulated switchgear according to claim 5, characterized in that the through-contacts ( 40 , 41 , 42 ) are galvanically connected via the sliding contacts ( 37 , 38 , 39 ) in the "on position" to the fixed inlet contacts ( 34 , 35 , 36 ) and, after reaching the "off position", to earthing contacts ( 44 , 45 , 46 ) designed as through-contacts provided in the wall ( 43 ) of the encapsulation housing ( 2 ). 7. Gas-insulated switchgear according to claim 6, characterized in that both the inlet contacts ( 34 , 35 , 36 ) assigned to the three phase conductors ( 5 , 6 , 7 ) of the busbar and the through contacts ( 40 , 41 , 42 ) assigned to the circuit breakers ( 8 , 9 , 10 ) are each arranged on a plane running in the axial direction of the encapsulation housing ( 2 ).