DE202015106726U1 - Gas-insulated high-voltage switch - Google Patents

Abstract

Gas-insulated high-voltage switch having two contact pieces (10, 20) which are movable in opposite directions to open and close the switch along an axis (A), and two coaxial contact systems (N, L), one of which is a rated current contact system (N) and the inner is an arcing contact system (L), the two contact pieces (10, 20) each having one of two rated current contacts (11, 12) of the rated current contact system (N) and one each of two arcing contacts (21, 22) of the arcing contact system (L). and wherein the rated current contact system (N) can be disconnected before opening the switch in front of the arcing contact system (L) and closable when closing the switch after the arcing contact system (L), characterized in that a first (11) of the two rated current contacts (11, 12 ) comprises at least one set of first (1) and a set of second contact fingers (2), wherein contacting ends (1a) of the first contact fingers (1) to At least axially or radially spaced from the contacting ends (2a) of the second contact fingers (2) are arranged.

Description

TECHNICAL AREA

The present invention relates to a gas-insulated high-voltage switch according to the introductory part of protection claim 1. Such a switch allows in the rated voltage range of about 10 kV up to several hundred kV, such as 123 kV or 365 kV, the shutdown higher, generally to 63 kA, amounting short-circuit currents. The switch includes two contact pieces which are movable in opposite directions for opening and closing the switch along an axis, and two coaxially arranged contact systems, one of which is a rated current contact system and the inner an arcing contact system. The two switching pieces each have a rated current contact of the rated current contact system and an arcing contact of the arcing contact system.

When the switch is opened, the rated current contact system is disconnected before the arcing contact system. When closing, the arc contact system is closed before the rated current contact system.

In order to achieve high contact separation speed when opening, the two contact pieces are driven in opposite directions to each other. The high contact separation speed achieved thereby reduces the drive energy required to actuate the switch as well as the dielectric behavior of the switch when interrupting a current.

STATE OF THE ART

Switches of the type mentioned are in US 5,578,806 and in WO 2014/096219 A1 described. These switches each contain in coaxial arrangement an external rated current contact system and an internal arcing contact system and two counter-movable contact pieces, each having a rated current contact of the rated current contact system and an arcing contact of the arcing contact system. The opposite movement of the two contact pieces is with a rack resp. achieved with a lever mechanism. For this purpose, a movable of a drive first two switching pieces via an insulating non-positively connected to the transmission, which in turn is connected via an output element frictionally connected to the second switching piece.

EP 2 309 526 A1 and in WO 2015/024840 A1 describe gas-insulated high-voltage switch with a rated current contact system, comprising two locally separated, electrically interconnected nominal current contacts and a rated current mating contact, contacted the two rated current contacts with the switch closed and separated with the switch open from the two rated current contacts. By using such a double contact system, a rated current flowing during operation of the switch in the rated current contact system is split into two current paths, thereby reducing unavoidable current losses in the rated current contact system.

PRESENTATION OF THE INVENTION

The invention, as indicated in the claims, is based on the object to improve the switching capacity and the current carrying capacity of the high voltage switch of the type mentioned.

According to the invention there is provided a gas-insulated high-voltage switch having two contact pieces which are movable in opposite directions to open and close the switch along an axis, and two coaxial contact systems, one of which is a rated current contact system and the inner is an arcing contact system. In this switch, the two switching pieces each have one of two rated current contacts of the rated current contact system and each one of two arcing contacts of the arcing contact system, and the rated current contact system when opening the switch before the arcing contact system separable and closable when closing the switch to the arcing contact system.

A first of the two rated current contacts has at least one set of first and one set of second contact fingers, wherein contacting ends of the first contact fingers are arranged at least axially or radially spaced from the contacting ends of the second contact fingers.

In the switch according to the invention, the two counter-rotating rated current contacts and the two locally separate sets of first and second contact fingers of the first rated current contact cause a high rated current carrying capacity and a good switching capacity. This is because the two sets of contact fingers of the first rated current contact and the second rated current contact form a large number of locally separate contact points with the switch closed, which reduce the current losses in Nennstromkontaktsytem and accordingly increase the rated current carrying capacity of the switch. On the other hand also because the current to be disconnected when opening the switch because of the spaced apart sets commutated with the first and second contact fingers in general largely stepwise into a current path containing the arc contact system, and since a formed when disconnecting the rated current contacts Kommutierungslichtbogen is extremely fast extended because of the counter-rotating rated current contacts and accordingly has a high, the commutation facilitating resistance. The disconnected current can therefore commute in a short time from the rated current contact system in the arcing contact system, which not only the rated current carrying capacity of the switch but also its switching capability can be improved without changing the dimensions of the switch.

The contacting ends of the first contact fingers may be held radially outwardly spaced from the contacting ends of the second contact fingers, and with the switch closed, the contacting ends of the first contact fingers on the shell surface and the contacting ends of the second contact fingers on the inner surface of the contact finger be designed as a hollow cylinder formed second of the two rated current contacts. The contacting ends of the first contact fingers may be axially spaced from the contacting ends of the second contact fingers. Radially inwardly facing finger edges of the second contact fingers can be mounted on a support ring which supports the contact-bearing ends of the second contact fingers with the switch closed to form a radially outwardly acting contact force.

Alternatively, the contacting ends of the first contact fingers may be axially spaced from the contacting ends of the second contact fingers, and with the switch closed, the contacting ends of the first and second contact fingers are supported to form contact force on the shell surface or on the inner surface of the hollow cylinder. In addition, at least one set of third and optionally a set of fourth contact fingers may be provided, the contact-bearing ends of which, when the switch is closed, contact the surface of the hollow cylinder facing away from the contacting ends of the first and second contact fingers. The contacting ends of the second contact fingers may be offset radially inwardly from the contacting ends of the first contact fingers, with the contacting ends of the second contact fingers contacting a portion of the shell surface of the hollow cylinder when the switch is closed, that of an annular step of a stepped end of the hollow cylinder is formed. The contacting ends of the first and the second contact fingers can also be arranged without offset in the radial direction.

At least one set of contact fingers may be attached to a portion of the first rated current contact formed as a contact ring.

At least one set of first contact fingers can be molded into the rated current contact.

The stroke of the arcing contact of one of the two contact pieces may be greater than the stroke of the rated current contact of the first contact piece when opening or closing the switch.

BRIEF DESCRIPTION OF THE DRAWINGS

With reference to drawings, embodiments of the invention will be explained in more detail below. Hereby shows:

1 a plan view of an axially guided section through a simplified illustrated embodiment of a high-voltage switch according to the invention when opening,

2 a more detailed representation of an in 1 in a border II located portion of a rated current contact system of the switch according to 1 , and

3 to 6 in each case a representation of four further rated current contact systems of the switch to 1 ,

WAYS FOR CARRYING OUT THE INVENTION

In the figures, like reference numerals refer to like-acting parts. The in 1 illustrated high-voltage switch is constructed with respect to an axis A substantially axially symmetrical and includes a metal or electrically insulating housing G, which is filled with an arc-quenching dielectric, in particular an insulating gas. The insulating gas may include air, N ₂ , O ₂ , CO ₂ , a noble gas, H ₂ , NO ₂ , NO, N ₂ O, SF ₆ or fluorocarbons, in particular perfluorocarbons, such as CF ₄ , CF ₃ I, and mixtures thereof. Also suitable as a dielectric are organic fluorine compounds and mixtures thereof with the abovementioned insulating gases, the organic fluorine compounds in particular containing fluorinated ethers, oxiranes, fluoramines, fluoroketones, fluoroolefins or fluoronitriles and mixtures thereof. The insulating gas is compressed to a pressure of up to several bars, typically 5 to 8 bars.

The housing G takes two contact pieces 10 . 20 on, which are movable in opposite directions to open and close the switch along the axis A and two coaxially arranged contact systems, of which an outer than rated current contact system N and the inner as Arc contact system L is formed. The rated current contact system N contains two rated current contacts 11 and 12 , the arc contact system L, however, two arcing contact 21 and 22 , The rated current contact 11 and the arc contact 21 are part of the contact piece 10 , the rated current contact 12 and the arc contact 22 are part of the contact piece 20 , The contact piece 10 also includes one with the contact pieces 11 . 21 firmly connected insulating nozzle 30 from a in the action of a switching arc quenching gas releasing material, such as in particular polytetrafluoroethylene (PTFE), and one of the rated current contact 11 radially outward and from the arcing contact 21 radially inward limited pressure chamber 40 for receiving extinguishing gas which is formed when interrupting a current from the switching arc and an optionally provided stroke-controlled compression device.

The switch further includes a lever gear 50 on that over a coupling link 51 with the insulating nozzle 30 , via a coupling link 52 with the rated current contact 12 and via a coupling link 53 with the arcing contact 22 is rotatably connected. The coupling link 51 is with a lever arm of a fixedly mounted angle lever 54 rotatably connected, however, are the coupling members 52 . 53 rotatably connected to the other lever arm of the angle lever. The rotatable connections are so to the angle lever 54 hinged that when opening or closing the switch, the coupling member 51 acts as a drive element and the coupling links 52 and 53 as output elements of the transmission 50 act, if the driving force of a drive D primarily on the contact piece 10 is transmitted. If the driving force by a drive D 'primarily to the second switching piece 20 is transmitted, such as by pivoting the angle lever 54 , so act the coupling links 51 . 52 and 53 as output elements. In any case, the lever mechanism causes 50 that when opening resp. Close the switch the two contact pieces 10 and 20 be moved in opposite directions. As a result, when the switch is opened, the contact separation speeds in the rated current contact system N and in the arcing contact system L are increased and, accordingly, the switching capacity of the switch is improved despite a small-sized drive D or D '. At the same time it is ensured that the rated current contact system N before the arc contact system L opens resp. the arc contact system L in front of the rated current contact system N closes.

It also ensures that the rated current contact 12 performs a lower stroke than the arc contact 22 , Therefore, the distance between the two rated current contacts 11 and 12 be considerably smaller dimensioned open switch than the distance between the two arcing contacts 21 and 22 , which allows a particularly compact design of the switch in the axial direction while maintaining a high dielectric strength in the off position.

From the 2 to 6 it can be seen that the rated current contact 11 as a structured tubular hollow body ( 2 to 5 ) or as a structured conical hollow body 11 ( 6 ) and the rated current contact 12 as largely structureless hollow cylinder 12 ( 2 to 6 ) is trained. It can be seen that the rated current contact 11 in all embodiments at least two sets of contact fingers 1 and 2 on. At least one of the two sets of contact fingers 1 respectively. 2 forms a hollow cylindrical or hollow conical structure. The contact fingers of each set are on a contact ring 111 formed portion of the rated current contact 11 held and can be formed for example by cutting in a cylindrical or conical metal tube made of a highly electrically conductive material, but also in an electrically conductive manner by material bond, such as welding or soldering, or by a mechanically detachable or non-detachable connection, such as screws, presses or Clamps, with the contact ring 111 be connected.

The rated current contacts 11 . 12 and in particular the contact fingers 1 . 2 can be made of a material with a high spring force at the same time good electrical conductivity, such as typically a copper-chromium-zirconium alloy exist. Alternatively, the contact fingers or at least part of the contact fingers may be made of a material that is particularly electrically conductive, such as copper.

The required contact force is achieved by loading the contact fingers 1 and 2 achieved with preload. This can be achieved by elastic deformation of the contact fingers when closing the switch and requires contact fingers, which are made of a highly electrically conductive alloy with high mechanical strength and good spring properties. On the other hand, contact fingers made of an electrically particularly highly conductive material, such as copper, require prestressed contact springs, which prevent premature relaxation of the contact fingers. As in 2 represented such contact springs in space-saving manner as a ring spring 112 be educated. The guided in the circumferential direction about the axis A ring spring 112 loads the contact fingers 1 , In particular, when closing the switch on the lateral surface 121 of the rated current contact 12 deferred, contact-giving ends 1a , radially inward with a biasing force and thus provides sufficient contact force between these outer contact fingers 1 and the rated current contact 12 , Radially inwardly pointing finger edges of the contact fingers 2 are on a likewise guided in the circumferential direction support ring 113 stored. The support ring 113 supports the inner contact fingers 2 , which with closed switch in the Current Rating Contact 12 are inserted, against a radially inwardly acting force from when pushing the contact fingers 2 on the inner surface 122 of the rated current contact 12 is produced. The contact fingers 2 are thus protected from the action of an undesirably large, radially inwardly directed bending force.

An example in 2 Shielding shown 114 surrounds the rated current contact 11 in a coaxial arrangement and is used to control the electric field in a before closing respectively. after disconnecting the two contact pieces 10 . 20 existing separation distance between the two rated current contacts 11 . 12 respectively. the two switching pieces 10 . 20 ,

When the switch is closed contact free ends 1a respectively. 2a the contact finger 1 respectively. 2 under the formation of contact force on the rated current contact 12 supported. It can then be connected to electricity 101 . 201 (shown in the 3 to 6 ) of the switch fed current through the rated current contact system N flow.

In all embodiments shown, the contacting ends 1a the contact finger 1 at least axially or radially spaced from the contacting ends 2a the contact finger 2 arranged. This will change the number of current transitions from the rated current contact 11 on the rated current contact 12 significantly increased. Because the highest current density and thus also the highest temperature increase at contact points of the contact finger ends 1a . 2a which occur on the rated current contact 12 rest, so by increasing the number of contact points lying on the current density and thus also the power losses in the individual contact points. in the individual contact fingers 1 . 2 reduced. As the power losses increase with the square of the current, the reduction is significant. It is essential that the current in each set of contact fingers 1 respectively. 2 evenly on the predominantly axially aligned contact fingers 1 respectively. 2 is split. This is achieved by the contact fingers 1 and 2 are formed and dimensioned equal in each of the two contact finger sets, and that the contact resistance of the contact ring 111 on the parallel current paths forming individual contact fingers 1 respectively. 2 in each of the contact finger sets are small and largely equal in size.

Therefore, the current losses in the rated current system N can be up to the opening of the rated current contacts 11 . 12 be kept low. As a Kommutierungslichtbogen formed when disconnecting the rated current contacts as a result of the counter-rotating nominal current contacts 11 . 12 is rapidly extended and accordingly has a high resistance, the current to be switched can commute in a short time from the nominal current contact system N in the arcing contact system L, which without changing the dimensions of the switch both the rated current carrying capacity and the switching capacity of the switch according to the invention are substantially improved.

In the embodiments of the 2 and 3 are the contacting ends 1a the contact finger 1 radially outward at a distance from the contacting ends 2a the contact finger 2 held. Furthermore, when the switch is closed resp. when opening the switch before disconnecting the rated current contacts 11 . 12 the contacting ends 1a the contact finger 1 on the lateral surface 121 and the contacting ends 2a the contact finger 2 on the inner surface 122 of the hollow cylinder 12 each supported by the formation of contact force. The contact ends 1a the contact finger 1 are also apparent axially spaced from the contacting ends 2a the contact finger 2 arranged. According to the embodiments 2 and 3 project beyond the contact ends 1a the contacting ends 2a , As dashed in 3 can be shown, the contact ends 2a but possibly also the contact ends 1a overtop. Optionally, the two contact finger sets can also extend in the axial direction of the same length, so that the contacting ends 1a respectively. 2a within a narrow ring section on the lateral surface 121 respectively. on the inner surface 122 of the rated current contact 22 rest. Due to the fact that the contacting ends 1a . 2a the contact finger 1 . 2 Radially offset from each other, the foot ends of the contact fingers 1 . 2 each arranged on circles with different diameters and accordingly easily in an electrically conductive manner on the contact ring 111 be attached. Out 2 it can be seen that this is done by inserting the foot ends of the contact fingers 1 respectively. 2 in an annular material recess 1111 respectively. in an annular groove 1112 of the contact ring 111 can be realized in a simple manner.

In the embodiment according to 4 are the contacting ends 1a the contact finger 1 axially spaced from the contacting ends 2a the contact finger 2 held. When the switch is closed then the contact ends 1a . 2a the contact finger 1 . 2 under the formation of contact force on the lateral surface 121 of the hollow cylinder 12 supported. The contact ends are visible 2a the contact finger 2 opposite the contacting ends 1a the contact finger 1 arranged radially offset inwardly and has the rated current contact 12 a graduated free end 123 on. When the switch is closed then contact the contact fingers 2 an annular step 124 of the graduated end 123 whereas the contact fingers 1 the lateral surface 121 of Contact end 123 to contact. As the contact ends 1a . 2a on the comparatively large lateral surface 121 of the rated current contact 12 rest, this embodiment enables the transmission of particularly large rated currents. Optionally, the two sets of contact fingers 1 . 2 also be arranged so that they only the inner surface 122 of the rated current contact 12 respectively. contact the hollow cylinder.

In the embodiment according to 5 There are also two sets of contact fingers 3 and 4 provided, the contacting ends 3a and 4a are arranged without spacing in the radial direction but only with axial distance from each other. The contact ends 3a and 4a are at closed resp. closing switch to form contact force on the cylindrical inner surface 122 of the hollow cylinder 12 supported. Therefore, the contact fingers 3 . 4 without offset in the radial direction on the contact ring 111 be attached, wherein a short contact finger in the axial direction 3 between two longer contact fingers in the axial direction 4 is arranged. A graduated end 123 can be omitted if all contact fingers 1 . 2 without clearance in the radial direction on the contact ring 111 are held.

In the embodiment according to 6 are in the difference to the embodiments according to the 2 to 5 the contact fingers 1 and 2 in a an inner cone having rated current contact 11 integrated.

LIST OF REFERENCE NUMBERS

A

 axis

L

 Arcing contact system

N

 Rated current contact system

1, 2, 3, 4

 contact fingers

1a, 2a, 3a, 4a

 contacting ends of the contact fingers

10

 switching piece

101

 power connection

11

 Rated current contact, hollow body

111

 contact ring

1111

 material recess

1112

 ring groove

112

 Ringfeder

113

 support ring

114

 shielding

12

 Rated current contact, hollow cylinder

121

Lateral surface of the hollow cylinder 12

122

Inner surface of the hollow cylinder 12

123

End of the hollow cylinder 12

124

 step

20

 switching piece

201

 power connection

21, 22

 Arcing contacts

30

 insulating

40

 pressure chamber

50

 lever mechanism

51, 52. 53

 coupling members

54

 bell crank

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 5578806 [0004]
• WO 2014/096219 A1 [0004]
• EP 2309526 A1 [0005]
• WO 2015/024840 A1 [0005]

Claims (11)

Gas-insulated high-voltage switch with two contact pieces ( 10 . 20 ) which are movable in opposite directions to each other for opening and closing the switch along an axis (A), and with two coaxially arranged contact systems (N, L), one of which is a rated current contact system (N) and the inner an arcing contact system (L) , wherein the two contact pieces ( 10 . 20 ) each one of two rated current contacts ( 11 . 12 ) of the rated current contact system (N) and in each case one of two arcing contacts ( 21 . 22 ) of the arcing contact system (L), and wherein the rated current contact system (N) can be disconnected when the switch is opened in front of the arcing contact system (L) and when the switch is closed after the arcing contact system (L), characterized in that a first ( 11 ) of the two nominal current contacts ( 11 . 12 ) at least one set of first ( 1 ) and a set of second contact fingers ( 2 ), wherein contacting ends ( 1a ) of the first contact fingers ( 1 ) at least axially or radially with distance from the contacting ends ( 2a ) of the second contact finger ( 2 ) are arranged. Switch according to claim 1, characterized in that the contacting ends ( 1a ) of the first contact fingers ( 1 ) radially outward at a distance from the contacting ends ( 2a ) of the second contact finger ( 2 ) and that, when the switch is closed, the contact-making ends (FIG. 1a ) of the first contact fingers ( 1 ) on the lateral surface ( 121 ) and the contacting ends ( 2a ) of the second contact finger ( 2 ) on the inner surface ( 122 ) as a hollow cylinder ( 12 ) trained second ( 12 ) of the two nominal current contacts ( 11 . 12 ) are supported. Switch according to claim 2, characterized in that the contacting ends ( 1a ) of the first contact fingers ( 1 ) axially spaced from the contacting ends ( 2a ) of the second contact finger ( 2 ) are arranged. Switch according to one of claims 2 or 3, characterized in that radially inwardly pointing finger edges of the second contact fingers ( 2 ) on a support ring ( 113 ), the contacting ends ( 2a ) of the second contact finger ( 2 ) is supported with the switch closed to form a radially outwardly acting contact force. Switch according to claim 1, characterized in that the contacting ends ( 1a ) of the first contact fingers ( 1 ) axially spaced from the contacting ends ( 2a ) of the second contact finger ( 2 ) and that, when the switch is closed, the contacting ends ( 1a . 2a ) the first ( 1 ) and the second contact finger ( 2 ) under the formation of contact force on the lateral surface ( 121 ) or on the inner surface ( 122 ) of the hollow cylinder ( 12 ) are supported. Switch according to claim 5, characterized in that at least one set of third ( 3 ) and possibly a set of fourth contact fingers ( 4 ), wherein the contacting ends ( 3a . 4a ) the third ( 3 ) and the optionally provided fourth contact fingers ( 4 ) with the switch closed, that from the contacting ends ( 3a . 4a ) of the first and second contact fingers ( 1 . 2 ) opposite surface ( 121 . 122 ) of the hollow cylinder ( 12 ) to contact. Switch according to one of claims 5 or 6, characterized in that the contacting ends ( 2a ) of the second contact finger ( 2 ) opposite the contacting ends ( 1a ) of the first contact fingers ( 1 ) are arranged offset radially inwards, wherein the contacting ends ( 2a ) of the second contact finger ( 2 ) with the switch closed, a portion of the lateral surface ( 121 ) of the hollow cylinder ( 12 ) coming from an annular step ( 124 ) of a stepped end ( 123 ) of the hollow cylinder ( 12 ) is formed. Switch according to one of claims 5 or 6, characterized in that the contact-bearing ends of the first and the second contact fingers are arranged without offset in the radial direction. Switch according to one of Claims 1 to 8, characterized in that at least the set of first ( 1 ) or second contact fingers ( 2 ) on a contact ring ( 111 ) formed portion of the first rated current contact ( 11 ) is attached. Switch according to one of Claims 1 to 8, characterized in that at least the set of first ( 1 ) or second contact finger ( 2 ) in the first rated current contact ( 11 ) is formed. Switch according to one of claims 1 to 10, characterized in that the stroke of the arcing contact ( 22 ) of a first ( 20 ) of the two contact pieces ( 10 . 20 ) when opening or closing the switch is greater than the stroke of the rated current contact ( 12 ) of the first contact piece ( 20 ).

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