WO2013092136A1

WO2013092136A1 - Phase conductor section having a current transformer for a polyphase gas-insulated switchgear assembly

Info

Publication number: WO2013092136A1
Application number: PCT/EP2012/073774
Authority: WO
Inventors: Joachim Baudach; Wojciech Olszewski; Caroline ORTH; Steffen Rautenberg
Original assignee: Siemens Aktiengesellschaft
Priority date: 2011-12-21
Filing date: 2012-11-28
Publication date: 2013-06-27
Also published as: DE102011089398A1

Abstract

The invention relates to a polyphase gas-insulated switchgear assembly (1). The switchgear assembly (1) comprises a circuit breaker which is arranged in a breaker housing (2), a distribution housing (3) and a phase conductor section for each phase, said phase conductor section running out of the breaker housing (2) into the distribution housing (3). In this case, each phase conductor section is individually routed between the breaker housing (2) and the distribution housing (3) in an encapsulation enclosure (4). A current transformer having at least one current transformer core (5) which is arranged on an outer surface of the respective encapsulation enclosure (4) is arranged on each encapsulation enclosure (4) for the phase conductor section routed in said encapsulation enclosure.

Description

description

PHASE conductor portion with current transformer for multiphase gas-insulated switchgear The invention relates to a multi-phase gas-insulated switchgear ^¬ plant, comprising a current transducer for each of its phases.

DE 10 2005 003 870 A1 discloses a housing assembly of a conductor track surrounded by electrical insulation. The conductor run is surrounded by a substantially tubular housing which has two electrically conductive housing sections which run around the conductor run and which are spaced apart from one another by an electrically insulating tube running around the conductor run. The housing assembly can be surrounded by egg ^¬ ner secondary winding of a current transformer whose primary winding is the Leiterzug.

The invention has for its object to provide an improved multi-phase gas-insulated switchgear, which has a current transformer for each of its phases.

The object is achieved by the features of claim 1. An ^¬ .

Advantageous embodiments of the invention are the subject of the dependent claims.

A multi-phase gas-insulated switchgear according to the invention comprises a arranged in a switch housing Leis ^¬ processing circuits, a partitioning body and ei ^¬ NEN phase conductor section for each phase, which extends from the switch housing in the partitioning body. Each phase conductor section is guided individually between the switch housing and the split housing in an encapsulation jacket. At each encapsulation ^¬ coat for the guided in it phase conductor section is a current transformer with at least one on an outer surface arranged the respective encapsulation jacket arranged current transformer core.

Thus, according to the invention, each phase between the power switch and the split housing is individually encapsulated by an encapsulation jacket. This makes it advantageous to arrange for each phase a current transformer having at least one außenlie ^¬ constricting current transformer core of the Kapselungsmantel the phase.

Each phase is led out directly and individually in their respective encapsulation jacket from the switch housing of the power ^{scarf ¬ age} . This is especially space-saving and component-saving compared to a lead out of the phases of the switch housing in a common capsule housing and a subsequent single encapsulation of the various phases. In addition to shortening the field length and reducing the field distribution of the switchgear, this design also allows larger core cross-sections of the current transformers and facilitates the assembly and maintenance of the switchgear.

In a preferred embodiment of the invention, the encapsulation jackets are each secured by a respective first Flanschverbin ^¬ tion on the switch housing of the circuit breaker.

Additionally or alternatively, the encapsulation shells are further fastened in each case by a respective second flange on the distribution housing. Flange connections advantageously allow a simple and secure connection of the Kapselungsmäntel with the Schalterge ^¬ housing and the housing division. In particular, they also simplify the installation and maintenance of the switchgear. Each encapsulation jacket is preferably tubular ^{ausgebil ¬} det and has a circular cylindrical outer surface in a central region. This geometric configuration of the particular Kapselungsmäntel is ^¬ It benefits in adapted to the array of current transformers with external current transformer cores.

In this geometric embodiment of the encapsulation shells, the current transformer cores are preferably annular and arranged around a portion of the central region of the respective encapsulation jacket.

This allows a particularly space-saving and expedient design and arrangement of the current transformer.

In the switch housing and / or in the partition housing, all phases are preferably encapsulated together.

As a result, an unnecessary individual encapsulation of the phases in the switch housing and / or the distribution housing is avoided or the individual encapsulation of the phases is advantageously limited to the necessary areas of the switchgear.

Further, the Kapselungsmäntel are preferably arranged parallel to each other ^¬. As a result, the installation space of the switchgear can be further reduced. In addition, the assembly and maintenance of the switchgear will be further facilitated.

In a further preferred embodiment of the invention, the switchgear on exactly three phases.

Three-phase switchgear is best adapted to the standard requirements and applications and therefore particularly advantageous embodiments of the invention. Preferably, the switch housing, the encapsulating jackets and the split housing together form a contiguous gas space for an insulating gas. Characterized the switch housing, the Kapselungsmäntel and the partitioning body may advantageously be charged together with an iso ^¬ liergas. Furthermore, there is in this manner in the switch housing, the Kapselungsmäntel and Auftei ^¬ development housing automatically the same pressure and this pressure can be easily controlled for the entire gas space.

In this case, the switch housing, the encapsulation jackets and the division housing are preferably formed overpressure resistant up to a defined pressure of the insulating gas and together form a overpressure to the defined pressure overpressure pressure vessel for the insulating gas.

This advantageously makes it possible to operate the switchgear with an insulating gas under an overpressure.

The above-described characteristics, features and advantages of the invention, as well as the manner in which they are achieved, will become clearer and more clearly understood in connection with the following description of an embodiment, which will be explained in connection with a drawing.

The drawing shows part of a three-phase switchgear gasiso ^¬ profiled. 1

The switchgear 1 comprises a arranged in a switch housing 2 circuit breaker, a distribution housing 3 and for each phase a phase conductor section, which consists of the

Switch housing 2 extends into the distribution housing 3. Each phase conductor section is guided individually between the switch housing 2 and the split housing 3 in an encapsulation jacket 4. At each encapsulation jacket 4, the led phase conductor section a current transformer with a plurality of arranged on an outer surface of the respective encapsulation jacket 4 Stromwandlerkerne 5 arranged. In the switch housing 2 and the partition housing 3, the three phases are each encapsulated together. Only between the switch housing 2 and the division housing 3, each phase is individually encapsulated by the respective encapsulating jacket 4. Each encapsulation jacket 4 is tubular, has a circular cylindrical Außenoberflä ^¬ che in its central region and is attached via a first flange 6 to the switch housing 2 and a second flange 7 to the distribution housing 3. The encapsulating shells 4 are arranged parallel to each other. A middle one of the first flange connections 6 is connected to each of the other two first flange connections 6 at the switch housing-side flange sections in each case via a connecting web 8. The current transformer cores 5 each disposed in each case ring-shaped and a portion of the central region of a Kapselungsmantels around 4, wherein its internal diameter ^¬ diert correspondent to the outer diameter of the cross section of the region of the respective mittle ^¬ ren Kapselungsmantels. 4

The switch housing 2, the encapsulation jackets 4 and the Auftei ^¬ ment housing 3 together form a pressure-resistant to a defined pressure and gas-tight pressure vessel with a contiguous gas space for an insulating gas with which the

Switchgear 1 is filled. Alternatively, however, a use of gas-tight barriers in the region of the first and / or the second flange 6, 7 may be provided, so that a division into separate gas chambers of the switch housing 2, the encapsulation shells 4 and the Verteilteilgehäu- ses 3 takes place. For this purpose, the switch housing 2, the Kapse ^¬ ment coats 4 and the split housing 3 and the flange Connections 6, 7 each overpressure resistant formed to the ^{defini ¬} th overpressure and the flange 6, 7 each have openings through which insulating gas from the respective encapsulating jacket 4 in the switch housing 2 and in the distribution housing 3 can flow. Furthermore, the flange 6, 7 are designed to be gas-tight to the outside, that is provided with seals that prevent leakage of insulating gas from the switchgear 1 through the flange 6, 7.

Although the invention has been further illustrated and described in detail by way of a preferred embodiment, it is not limited by this disclosed example, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

Reference sign list

1 switchboard

2 switch housings

3 distribution housing

4 encapsulating jacket

5 current transformer cores

6 first flange connection

7 second flange connection 8 connecting web

Claims

claims

1. A multi-phase gas-insulated switchgear (1) comprising a in a switch housing (2) arranged circuit breaker, a distribution housing (3) and for each phase a phase ^¬ conductor section extending from the switch housing (2) in the on ^{¬ distribution} housing (3) wherein each Phasenleiterab ^{¬ section} between the switch housing (2) and the division ^¬ housing (3) individually in a Kapselungsmantel (4) is guided, and wherein at each Kapselungsmantel (4) for the guided in it phase conductor section a current transformer with wenigs ^¬ least a arranged on an outer surface of the respective Kapse ^¬ ment jacket (4) is arranged current transformer core (5).

2. Multi-phase gas-insulated switchgear (1) according to claim 1, e g e n e c e n e d d e r c h

in each case a first flange connection (6) for each encapsulation jacket (4), via which the encapsulation jacket (4) is fastened to the switch housing (2).

3. Multiphase gas-insulated switchgear (1) according to one of the preceding claims,

marked by

depending on a second flange (7) for each Kapselungsmantel (4) over which the Kapselungsmantel (4) is fixed to the Auftei ^¬ lung housing (3).

4. Multiphase gas-insulated switchgear (1) according to one of the preceding claims,

characterized ,

each encapsulation jacket (4) is tubular and has a circular-cylindrical outer surface in a middle region.

5. Multi-phase gas-insulated switchgear (1) according to claim 4, characterized is that each current transformer core (5) ring-shaped and disposed about a portion of the central region of the respective Kapse ^¬ lung jacket (4) around.

6. Multiphase gas-insulated switchgear (1) according to one of the preceding claims,

characterized ,

that all phases in the switch housing (2) are gekap ^¬ together.

7. Multiphase gas-insulated switchgear (1) according to one of the preceding claims,

characterized ,

that all phases in the distribution housing (3) are encapsulated together.

8. Multiphase gas-insulated switchgear (1) according to one of the preceding claims,

characterized ,

in that the encapsulation jackets (4) are arranged parallel to one another.

9. Multiphase gas-insulated switchgear (1) according to one of the preceding claims,

characterized ,

that the switchgear (1) has exactly three phases.

10. Multiphase gas-insulated switchgear (1) according to one of the preceding claims,

characterized ,

the switch housing (2), the encapsulation jackets (4) and the partition housing (3) together form a continuous gas space for an insulating gas.

11. Multi-phase gas-insulated switchgear (1) according to claim ^¬ 10,

characterized , are that the switch housing (2), the Kapselungsmäntel (4) and the partitioning body (3) via pressure-resistant up to a defi ^¬ ned pressure of the insulating gas formed and ge ^¬ jointly form a up to the defined overpressure überdruckfes- th pressure container for the insulating gas.