DE102006001237A1 - Three-phase insulated high voltage switch gear, has supporting unit with insulating connector provided between circuit breaker and bus bar region, where connector is formed such that circuit breaker is stabilized in its position - Google Patents

Abstract

The switch gear has several system components arranged in an enclosure housing. A terminal box (11) arranged as an enclosure bushing is provided in the housing for each phase. A supporting unit is rigidly connected with the housing, and is provided with an insulating connector (18) between a circuit breaker (24) and a bus bar region (9). The connector is formed such that the circuit breaker is stabilized in its position. A mechanical switching impulse is derived during the switching of the circuit breaker.

Description

The The invention relates to a gas-insulated, in particular three-phase encapsulated High-voltage switchgear.

such Switchgears are basically known.

Thus, the document discloses DE 199 57 392 A1 a gas-insulated, three-phase encapsulated switchgear with several arranged in a metal enclosure housing system components, in which the encapsulating for each phase axially behind one another designed as Kapselungsdurchführung power connector, a circuit breaker and a combined isolation-ground switch are arranged, and following the combined Cross-Sectional Ground-Breaker "Power Terminal Breaker Disconnect / Ground Switch" is a bus bar whose phase conductors are supported on the enclosure housing. The underlying object of the switchgear disclosed in the publication is to provide a switchgear that is suitable for high voltage purposes, and is characterized by the smallest possible space and ease of mounting.

disadvantage the switchgear shown in the cited document is that due to the fact that the system components are arranged axially one above the other are and support each other, the arrangement especially for switching pulses or horizontal Position of the switchgear is mechanically stressed particularly strong and accordingly vulnerable is.

task The present invention is thus to provide a switchgear, which a mechanically stable arrangement of the system components and in particular can be arranged horizontally, and in which the system components also before a mechanical load by Protected switching pulses are.

The Invention solves this object by a switchgear according to the independent claim.

Thereby, that in the encapsulating housing one with the encapsulating housing rigidly connected support device arranged with a between circuit breaker and busbar space Insulating connector is provided, which is designed such that the circuit breakers are stabilized in their position and a When switching the circuit breaker occurring mechanical switching pulse on the grounded encapsulating is derived, in particular the mechanical loads are intercepted, in particular in a horizontal arrangement of the switchgear act on the interfaces or connection points of the system components, as well as the plant components against strong mechanical pulses, when switching the circuit breaker, in particular circuit breakers with end contacts, such as vacuum switches, as well as the Transport can occur protected.

The Supporting device according to the invention also for a vertical arrangement advantageous because of the support device at least partially the weight of the system components are included can, thereby reducing the mutual burden of each other Components is reduced.

The support over the Isolierverbinder, which also takes over the function, the Phases to isolate each other and the encapsulating.

advantageous Further developments of the invention are described in the dependent claims.

A advantageous development of the invention provides that the Isolierverbinder for the execution the phase has electrodes made of an insulating matrix are surrounded.

Preferably the electrodes are embedded in the insulating matrix, whereby on the one hand ensures the mechanical stability of Isolierverbinders can be, and on the other undesirable gaps between Electrodes and isolation matrix are excluded.

A Further advantageous development of the invention provides that the insulating connector is formed in the form of a flat plate.

These Shape is useful when the circuit breakers of the phases on one common height to lock.

Possibly are all Electrodes of a common insulating matrix, by which preferably Also formed is the shape of the plate.

A Further advantageous development of the invention provides that the support device grounded shielding means by which the circuit breaker at least partially electrically shielded from each other.

The electrical shielding ensures that each circuit breaker experiences the same voltage stress during switching, ie all circuit breakers are subjected to the same load. This makes it possible to perform an accurate single-pole performance test, since by the Ab shielding the influence of the other phases on the phase to be measured is suppressed. The advantageous development can be dispensed with costly multi-pin development tests and certification tests, since single-pole performance tests are sufficient.

It is not mandatory that the circuit breakers on their entire length shielded from each other. So can the shield, how preferred according to the invention, restrict to the area of the switching chambers of the circuit breaker. In this case would on the almost entire length the switching chambers a "ladder-earth" shape of the electrical Field present.

Prefers the shielding means are formed by metal plates between the the circuit breakers are arranged.

A Further advantageous development of the invention provides that the supporting device several, preferably at least three, support bolts and a centering pin having the support bolts, preferably evenly, around the phases are arranged and connected to the encapsulating housing carriers support, and the centering bolt arranged in the common center of the phases is, and from the support bolts of the Insulated connector is worn.

Of the Centering pin is advantageously in the center of the Isolierverbinders fixed to the insulating connector.

possibly are the metal plates for the shield of the circuit breaker according to the invention preferred arranged between the centering pin and a support pin and preferably over the Support plunger with the encapsulating housing electrically connected and thus grounded. The number of support bolts depends on this Trap advantageous according to the number of circuit breakers. In a three-phase Plant with three circuit breakers according to the invention are three support bolts preferably, so that by the between the support pin and the centering pin arranged metal plates are formed three shielded chambers, in each of which one of the circuit breakers is located.

A advantageous development of the invention provides that between Insulating connector and busbar compartment Separating earthing switch provided The phases of the insulating connector are the busbar space respectively.

In this case can advantageously not only the circuit breakers, but also disconnecting earthing switches be supported by means of the Isolierverbinders of the support device.

A Further advantageous development of the invention provides that the circuit breaker of a phase has a switching chamber and a gear housing, the transmission case is arranged between the cable end closure and switching chambers, and at the encapsulating housing a crankcase is provided, with which the circuit breaker operable are.

Especially can in a multipolar, for example, three-pole, plant all Circuit breaker operated with a single crankcase.

A Further advantageous development of the invention provides that the encapsulating housing at a height above the crankcase and below the Isolierverbinders in a gas-tight interconnected pot part and headboard divided.

These Division of the encapsulating has significant benefits for the assembly of the switchgear.

So the switchgear can be almost completely built up in the pot part become. If appropriate, combined disconnecting earthing switches are preferred for this purpose, Support device with insulating connector, circuit breaker and cable terminations in the cup part arranged, and the busbar space in the headboard.

After that the headboard is over slipped the pot part and the final compound is made. For making the end connection For example, in the head part of a manhole can be provided over which the Interior of the encapsulating housing accessible in the necessary places is. The lid of the manhole may additionally have a diffusion filter take up.

For the connection of pot part and head part preferably have pot part and head part a flange on.

Possibly is the carrier for the Support plunger the support device in the edge area of the opening provided the pot part. In this way, the support device is located easily accessible above the opening of the cup part.

For the three-pole Switchgear with single-pole cable terminations is the pot part of the housing - in plan view - preferably triangular with rounded corners. This grants for one rectilinear crankcase of the switch drive a favorable linear Arrangement and ensures optimal spatial utilization of the base area for the cable terminations.

Of the Structure of a particular according to the invention Three-phase encapsulated switchgear can be basically also transferred to the construction of a single-phase switchgear.

In In this case can be dispensed with shielding and centering become. In this case, the insulating connector is preferably formed as a plate and integrated directly into the flange connection of pot and headboard.

The Invention will now be described with reference to an embodiment which by two figures is shown, closer explained.

there shows:

1 a gas-insulated, three-phase encapsulated switchgear according to the invention in a side view,

2 a plan view of the insulating connector used in the three-phase switchgear, and

3 a gas-insulated, single-phase encapsulated switchgear according to the invention in a side view.

1 shows a gas-insulated, three-phase encapsulated switchgear according to the invention in a side view.

The switchgear according to the invention has a metal encapsulating housing 1 which is substantially tubular. The encapsulating housing 1 consists of two parts, a basic body in the form of a pot 4b with cast base plate 10 and a headboard 4a together. headboard 4a and cup part 4b have a flange 5a respectively. 5b on, over which the two parts by means of a screw connection 3 connect gas-tight.

The switchgear has several encapsulating housings 1 arranged system components, wherein in the encapsulating 1 for each phase axially one behind the other designed as an encapsulation cable termination 11 and a circuit breaker are arranged, and behind the circuit breaker, the three phases via a combined isolating earthing switch 20 (also referred to as "three-positioner") a busbar space 9 are fed.

Furthermore, the switchgear in the encapsulating housing 1 one with the encapsulating housing 1 rigidly connected supporting device with a between circuit breaker and combined disconnecting earthing switch 20 arranged Isolierverbinder 18 on.

The insulating connector 18 is designed as a flat plate. It has three electrodes embedded in an isolation matrix, through which one phase is passed from the power switch to the combined isolation ground switch. Furthermore, in Isolierverbinder 18 a plurality, preferably three, openings provided which equalize the pressure in the encapsulating housing 1 enable.

The insulating connector 18 is directly between combined isolation ground switch 20 and circuit breakers arranged perpendicular to the axial alignment of the plant components, which in this case is made possible by the fact that the plant components complete circuit breaker and combined isolating earthing switch for all phases at a common level.

The busbar room 9 is in the headboard 4a of the encapsulating housing 1 arranged.

Support device with Isolierverbinder 18 , Disconnecting earthing switch 20 , Circuit breaker and cable terminations are arranged in the cup part.

The circuit breaker of a phase described in this embodiment has a switching chamber 15 , which is designed here as a vacuum interrupter, and a transmission housing 12 on. The gearbox 12 is between cable termination 11 and switching chambers 15 arranged.

On the outer shell of the encapsulating housing 1 is at the height of the circuit breaker via a crankcase connection 7 a crankcase 14 connected by means of the shift rods 13 located in the interrupters 15 can be operated switch.

Furthermore, the pot part 4b in the lower area between the crankcase 14 and base plate 10 on the outside of the encapsulating housing 1 a voltage transformer connection 8th on to which a container with a three-pole voltage transformer 22 connected.

The support device has three support bolts 19 and a centering bolt 21 made of metal. The three support bolts are at the level of the switching chambers 15 arranged evenly around the three phases and are based on each with the encapsulating 1 connected metallic carrier neck 6 from. In addition, are carrier neck 6 and support bolts 19 non-positively connected here via screw. The centering bolt 21 is arranged in the common center of the three phases, also at the level of the switching chambers 15 , with an axial alignment common to the three phases. The carrier neck 6 the individual support bolts 19 be by protrusions on the In nenseite the encapsulating 1 formed in the edge region of the opening of the cup part 4b above the crankcase 14 are poured.

By support bolts 19 and centering bolts 21 together, the Isolierverbinder 18 worn, with insulating connector 18 and bolts are additionally fixed to each other via a screw connection.

The cable terminations 11 are intended for the inclusion of power cables (not shown here). On these caddle closures 11 are the gearboxes 12 attached frictionally. The gearboxes have a cast aluminum body with lateral recesses through which the shift rails 13 be guided, and in the crankcase 14 attack on a common drive shaft. On the gearbox 12 sit the switching chambers 15 Loose, they are in an appropriate version of the gearbox 12 guided. The switching chambers 15 are over a narrow pot lid 16 with the electrodes 17 placed in the insulating connector 18 are cast in, positively connected.

By this type of connection are the switching chambers 15 practically to the insulating connector 18 attached: The hard pulse when switching on the circuit breaker is thus directly over the Isolierverbinder 18 and its support via the support bolts 19 on the carrier neck 6 and thus on the rigid pot part 4b derived. That the jacket of the switching chamber 15 forming porcelain remains through the suspension of the switching chambers 15 almost unloaded.

On the opposite side of the cast-in electrode 17 becomes the foot of the combined disconnect grounding switch 20 belonging contact housing screwed. This is a continuous conductive connection between cable entry to the separation point one in the busbar space 9 lying, not shown here, busbar disconnector made.

The insulating connector 18 fulfills a second function: It forces a stable mechanical position of the three switchgear columns 15 in a stable triple bundle. This provides a reliable guidance of the drive linkage of the switchgear poles in the vacuum circuit breaker used here and in the combined isolating earthing switch 20 guaranteed.

Furthermore, the support device has shielding means, by means of which almost the entire switching chambers 15 electrically shielded from each other.

As a result, the insulating connector fulfills a third function. According to the state of the art as well as the international regulations, the arrangement of three phases in a common housing requires proof of performance for a three-pole module, ie the more cost-effective single-pole power tests are not allowed as test proof due to possible mutual influence of the phases. On the other hand, the electrical shielding allows the three phases in the area of the switching chamber 15 a "real", that is, unaffected by the other phases, conductor-earth arrangement and thus a single-pole performance, despite three-pole switch panel.

The conductor-earth arrangement is achieved as follows. The centering bolt 21 of the insulating connector 18 contains on its lateral surface three axially extending joints, which in the direction of the support bolts 19 are oriented. The support bolts 19 contain appropriate joints that the respective joint of the centering pin 21 are opposite.

Between The three pairs of joints metal plates are inserted, for example, by suitable nubs are electrically contacted.

Because the three support bolts 19 over the encapsulating housing 1 grounded, also make the star-shaped, through the metal plates 2 created "cages" real ladder-earth arrangements.

2 shows the top view of the entire surface of the Isolierverbinders 18 and its arrangement in the cylindrical encapsulating housing 1 ,

Shown are the cast-in electrodes 17 of the insulating connector 18 , which are arranged in a triangular shape typical for three-phase systems. Furthermore, the carrier nozzles 6 on the inner wall of the encapsulating housing 1 visible, as well as the centering pin 21 with the three joints, which are in the middle of the encapsulating housing 1 are arranged hanging, and the metal plates 2 as Schirmungsplatten for the area between the three switching chambers 15 ,

by virtue of the described arrangement is a real "conductor-earth arrangement" implemented in which a mutual Influencing the switching chambers does not occur when switching. It is also omitted in this Range the stress of the switching chamber with the full mains voltage from "ladder-ladder", it's just the Voltage "conductor-earth" on.

Also in 2 it can be seen that the pot part 4b according to the arrangement of the phases is triangular with rounded corners. On an outside of the pot part 4b is the (in the drawing only hinted) rectilinear crankcase 14 buildin Untitled.

3 shows a gas-insulated, single-phase encapsulated switchgear according to the invention in a side view.

Similar to the described three-phase switchgear, the single-phase switchgear has a metallic grounded encapsulating housing 31 on which is in a headboard 32a and a pot part 32b is divided. headboard 32a and cup part 32b each have a flange 33a and 33b via which both parts can be connected to one another in a gas-tight manner by means of a screw connection.

Furthermore, in the cup part 32b of the encapsulating housing 31 axially one behind the other designed as an encapsulation cable termination 23 , a circuit breaker 24 that is at a height with the flange 33b of the cup part 32b completes, and a disconnect-ground switch 26 arranged, in turn, the phase one in the header 32a arranged busbar space 25 supplies.

The circuit breaker 24 divided into a cable termination 23 adjacent transmission housing 29 and one on the gearbox 29 subsequent switching chamber 30 , Furthermore, on the outside of the encapsulating 31 in the area of the pot part 32b a crankcase 28 provided with the circuit breaker 24 can be operated.

Between circuit breakers 24 and the disconnect ground switch 26 a support device is provided.

The support device consists in this embodiment of an insulating connector 27 As a flat plate with a flange 33a or flange 33b appropriate extent is formed. The insulating connector 27 has an electrode embedded in an insulation matrix in the center 28 through which the circuit breaker and the disconnect ground switch 26 are electrically connected to each other.

The insulating connector 27 is in the flange connection of cup part 32a and headboard 32b integrated. It lies with the outer edge area both on the flange 33a as well as on the flange 33b on and is clamped gas-tight by these above-mentioned screw.

breakers 24 and disconnect grounding switch 26 are via a screw connection with the electrode 28 of the insulating connector 27 connected. The insulating connector 27 thus supports in analogy to the embodiment of the three-phase switchgear both the circuit breaker and the disconnection-earthing switch 26 mechanically on the housing, but still ensures sufficient isolation of the phase of the grounded enclosure housing 31 ,

The insulating connector 27 has recesses that provide quick pressure equalization between pot and head, especially when an internal arcing fault occurs.

Claims (10)

Gas-insulated, in particular three-phase, encapsulated high-voltage switchgear, with several in an encapsulating housing ( 1 . 31 ) arranged system components, wherein in the encapsulating ( 1 . 31 ) for each phase axially one behind the other designed as an encapsulation cable termination ( 11 . 23 ) and a circuit breaker are arranged, and behind the circuit breaker, the phases of a busbar space ( 9 . 25 ), characterized in that in the encapsulating housing ( 1 . 31 ) one with the encapsulating housing ( 1 . 31 ) rigidly connected supporting device with a between circuit breaker and busbar space ( 9 . 25 ) arranged Isolierverbinder ( 18 . 27 ) is provided, which is designed such that the power switches are stabilized in their position and a occurring during switching of the circuit breaker mechanical switching pulse via the encapsulating ( 1 . 31 ) is derived. Plant according to claim 1, characterized in that the insulating connector ( 18 . 27 ) for the implementation of the phases electrodes ( 17 ) surrounded by an insulating matrix. Plant according to one of the preceding claims, characterized in that the insulating connector ( 18 . 27 ) is formed in the form of a flat plate. Installation according to one of the preceding claims, characterized in that that the supporting device ( 18 . 27 ) earthed shielding means by means of which the circuit breakers are at least partially electrically shielded from each other. Installation according to claim 4, characterized in that the shielding means by metal plates ( 2 ) are formed, which are arranged between the circuit breakers. Installation according to one of the preceding claims, characterized in that the supporting device a plurality, preferably at least three, support bolts ( 19 ) and a centering bolt ( 21 ), wherein the support bolts ( 19 ), vorzugswei se are arranged uniformly around the phases and are connected to the encapsulating housing ( 1 . 31 ) ( 6 ), and the centering pin ( 21 ) is arranged in the common center of the phases, and of the support bolts ( 19 ) of the insulating connector ( 18 . 27 ) will be carried. Installation according to one of the preceding claims, characterized in that between Isolierverbinder ( 18 . 27 ) and busbar space ( 9 . 25 ) Isolation grounding switch ( 20 . 26 ) are provided, the phases of the Isolierverbinder ( 18 . 27 ) the busbar space ( 9 . 25 ) respectively. Installation according to one of the preceding claims, characterized in that the circuit breaker of a phase, a switching chamber ( 15 . 30 ) and a transmission housing ( 12 . 29 ), wherein the transmission housing ( 12 . 29 ) between cable termination ( 11 . 13 ) and switching chambers ( 15 . 30 ) and on the encapsulating housing ( 1 . 31 ) a crankcase ( 14 . 28 ) is provided, with which the circuit breaker are operable. Plant according to claim 8, characterized in that the encapsulating housing ( 1 . 31 ) at a height above the crankcase ( 14 . 28 ) and below the Isolierverbinders ( 18 . 27 ) in a gas-tight interconnectable pot part ( 4b . 32b ) and headboard ( 4a . 32a ). Installation according to Claim 9 in conjunction with Claim 6, characterized in that the, preferably three, supports ( 6 ) in the connection region of the cup part ( 4b . 32b ) with the head part ( 4a . 32a ) are arranged and the support bolts ( 19 ) for the insulating binder ( 18 . 27 ) record frictionally.