DE19542529C1 - Fixed choke arrangement for testing HV systems e.g. gas-insulated switchgear or cables - Google Patents

Abstract

The throttle arrangement has at least one throttle coil (2,3) arranged in a metal housing (1). The throttle coil (2,3) is formed as an air coil without an iron core with a central support (5). Preferably at least two throttle coils (2,3) are fastened spaced apart from each other by an axial distance (4) on the electrically insulating central support (5). On the sides nearest the central support (5) the coils (2,3) have a voltage terminal. A first voltage terminal of a first coil (2) is fed to an axial side of the metal housing (1). A second terminal of a second coil (3) is fed to the other axial side of the housing (1). The throttle coils (2,3) preferably have further voltage terminals on their sides furthest from the central support (5). These are electrically connected to each other by a connection line (21). the central support (5) is preferably tubular and may be made of a glass fibre reinforced plastic or porcelain.

Description

The invention relates to a fixed throttle arrangement for the Testing of high-voltage systems, with at least one in one Metal housing arranged choke coil.

For testing capacitive test objects, for example of it is gas-insulated switchgear or cables with high voltage known to resonance circuits with variable excitation frequency use. The resonance circuit is determined by the capacitance of the Test object and with a fixed choke to be provided a fixed inductance. (See, for example, "On-site high voltage test technology for cables from SIEMENS, 2 text pages, undated). Known fixed chokes are usually housed in an oil-filled housing that has a considerable weight and volume. Such Throttle arrangements are difficult to handle and have to Testing a high-voltage system can be set up externally. This could cause electromagnetic interference from outside Influence test results.

DE-AS 12 87 203 is suitable for high voltage Fixed throttle arrangement with a variety of in one Metal housing arranged choke coils known as Air coils without an iron core with a central insulator are trained. The individual air coils are closed tubular coil groups stacked one on top of the other, the Coil groups, for their part, are nested concentrically are arranged. In each tubular coil group is the first coil connected to the high voltage connection. Therefore occurs in the radially outer coil group high-voltage conductor relatively close to the metal housing lie. However, there is a risk of voltage flashovers on the metal case.

The object of the invention is a relatively compact and lightweight Fixed choke arrangement for testing high-voltage systems specify which is easy with improved high voltage strength  manageable and preferably directly to the high-voltage system can be flanged to shield interference from the outside.

The problem is solved with the features of the claim 1.

The solution according to the invention has the advantage that by omission of the iron core, the weight of the fixed throttle is reduced. The central support replaces the support effect of the missing Iron core. The metal housing can be connected to the high voltage system can be easily flange-mounted. Then it lies on Earth potential. The two choke coils are so according to the invention switched that a on their radially outer sides medium voltage against the metal case and not the highest voltage occurring in the throttle arrangement. This measure allows a smaller distance between the outer sides of the choke coils and the metal housing, whereby a more compact design is made possible. The electrical insulation and thus the compactness of the system can still be achieved be improved that the metal housing with an insulating gas, for example SF₆ is filled under high pressure. The biggest Differences in tension occur between the first Voltage connection of the first choke coil and the second Voltage connection of the second choke coil on the radial inner side. Because of the electrically insulating central support and the axial distance between the Choke coils and because of the missing iron core it can be here  unwanted discharges do not occur. Conveniently are the first and the second voltage connection in each opposite axial directions from the metal case led out.

In a preferred embodiment, the central support is designed tubular. This will increase the weight of the Fixed throttle arrangement further reduced.

The central support preferably consists of glass fiber reinforced plastic or porcelain.

The arrangement according to the invention is in terms of dielectric strength Surges and an even potential curve thereby improved that the choke coils with cylindrical Field control electrodes are provided that a first and a second field control electrode each have a smaller diameter has and radially inside between the associated choke coil and the central support is arranged, and that a third and a fourth field control electrode each a large one Has diameter and radially outside around the associated Choke coil is arranged around.

With such an arrangement of the field control electrodes it is recommended that the first field control electrode with the first voltage connection of the first choke coil and the second Field control electrode with the second voltage connection second choke coil is connected that the third and the fourth field control electrode via the connecting conductor are connected and both on the same middle electrical potential.

In a preferred embodiment it is provided that the Metal housing made of a non-ferromagnetic material consists. This will prevent the formation of eddy currents and Hysteresis losses and the associated damping of the  Resonance circuit reduced. The quality of the resonant circuit is elevated.

The throttle arrangement according to the invention is particularly good for Use in a high voltage test circuit for testing of capacitive test objects.

An embodiment of the invention is described below the drawings explained in more detail.

Show it:

Fig. 1 is a partially sectional view of a throttle arrangement of the invention,

Fig. 2 shows an electrical test circuit using the choke arrangement according to the invention.

The choke arrangement according to the invention has a metal housing 1 , in which two choke coils 2 , 3 are fixed at an axial distance 4 from one another on an electrically insulating central support 5 . The central support 5 is tubular and consists of glass fiber reinforced plastic or porcelain. The metal housing 1 has a housing body 6 which is essentially circular in cross section and which has round openings on the axial sides located above and below. The underside of the housing body 6 is closed with a base plate 7 , in the middle of which the lower end 8 of the support 5 is anchored. The upper end of the support 5 is connected to a high-voltage connection 9 which projects through a window insulator 10 . The window insulator 10 is fastened on a cover flange 11 , which closes the opening on the upper axial side of the housing body 6 . The end section 12 of the high-voltage connection 9 protruding from the window insulator 10 is connected to the high-voltage system for testing.

The choke coils 2 , 3 are provided with cylindrical field control electrodes 13 , 14 , 15 , 16 , a first field control electrode 13 and a second field control electrode 14 each having a small diameter and being arranged radially on the inside between the associated choke coil 2 , 3 and the central support 5 . A third and a fourth field control electrode 15 , 16 have a larger diameter and are arranged radially on the outside around the associated choke coil 2 , 3 .

The choke coils 2 , 3 each have a voltage connection (not shown ) on their sides facing the central support 5 , a first voltage connection on the first choke coil 2 being connected to the first field control electrode 13 and a second voltage connection of the second choke coil 3 being connected to the second field control electrode 14 . The first voltage connection is connected to the high-voltage connection 9 via the first field control electrode 13 and a first feed line 17 and is led out on the upper axial side of the metal housing 1 . The second voltage connection is led out of the metal housing 1 in an electrically insulated manner via the second field control electrode 14 and a second feed line 18 on the lower axial side and is connected to a terminal 19 of a switch box 20 . The isolation is carried out for 5 to 20 kV, usually 10 kV. Finally, the third and fourth field control electrodes 15 , 16 are on the one hand electrically connected to the remaining voltage connections (not shown) of the choke coils 2 , 3 and on the other hand to one another by means of a connecting conductor 21 .

With the arrangement according to the invention, the distance 22 between the radially outer field control electrodes 15 , 16 and the inside of the housing body 6 can be very small.

Fig. 2 shows schematically the application of the throttle arrangement 2 according to the invention, 3 when considering a symbolized by a capacitor 23 high-voltage installation. With the help of a frequency generator 24 an alternating voltage with a variable frequency z. B. generated in the range between 20 and 300 Hz. The AC voltage is stepped up by means of a relatively small transformer 25 , with the 5th order of magnitude in the line 26 leading to the choke arrangement 2 , 3 . .20 kV occur. The line 26 is connected to the throttle arrangement 2 , 3 at the terminal 19 . The two choke coils 2 3 of the choke arrangement are connected to one another by the connecting conductor 21 . Finally, the feed line 17 leads to the high-voltage connection 9 , to which the high-voltage system 23 is connected.

To test the high-voltage system 23 , the frequency of the frequency generator 24 is varied until the resonant circuit formed from the inductance of the choke arrangement 2 , 3 and the capacitance 23 of the high-voltage system is in resonance. In the event of resonance, the desired test voltage is set at the high-voltage connection 9 . In this case, only the ohmic losses in the resonant circuit 2 , 3 , 23 have to be supplied by the frequency generator 24 and the transformer 25 .

Claims (6)

1. Fixed choke arrangement for testing high-voltage systems, in which at least two choke coils ( 2 , 3 ) designed as air coils without an iron core are fixed at an axial distance ( 4 ) to one another on an electrically insulating, central support ( 5 ), the choke coils ( 2 , 3 ) each have a voltage connection on their sides facing the central support ( 5 ), a first voltage connection of a first choke coil ( 2 ) on one axial side of the metal housing ( 1 ) and a second voltage connection of a second choke coil ( 3 ) on the other axial side is led out of the metal housing ( 1 ), and the choke coils ( 2 , 3 ) have further voltage connections on their sides facing away from the central support ( 5 ), which are electrically connected to one another by a connecting conductor ( 21 ). 2. Fixed throttle arrangement according to claim 1, characterized in that the central support ( 5 ) is tubular. 3. Fixed throttle arrangement according to claim 1 or 2, characterized in that the central support ( 5 ) consists of glass fiber reinforced plastic or porcelain. 4. Fixed throttle arrangement according to claim 2 or 3, characterized in that the choke coils ( 2 , 3 ) are provided with cylindrical field control electrodes ( 13 to 16 ), that a first and a second field control electrode ( 13 , 14 ) each have a smaller diameter and is arranged radially on the inside between the associated choke coil ( 2 , 3 ) and the central support ( 5 ), and in that a third and a fourth field control electrode ( 15 , 16 ) each have a larger diameter and radially on the outside around the associated choke coil ( 2 , 3 ) is arranged around. 5. Fixed throttle arrangement according to claim 4, characterized in that the first field control electrode ( 13 ) with the first voltage connection of the first choke coil ( 2 ) and the second field control electrode ( 14 ) with the second voltage connection of the second choke coil ( 3 ) is connected in that the third and the fourth field control electrode ( 15 , 16 ) are connected to one another via the connecting conductor ( 21 ) and both are at the same average electrical potential. 6. Fixed throttle arrangement according to one of the preceding claims, characterized in that the metal housing ( 1 ) consists of a non-ferromagnetic material.