KR101733899B1 - Surge arrester - Google Patents

Abstract

The present invention relates to a surge arrester (1) having a fluid-tight housing (2). The housing has a ground contact 3 and a high voltage contact 4 and the ground contact 3 and the high voltage contact 4 respectively electrically connect the inside of the housing 2 with the outside. The discharge element 5 arranged in the housing 2 comprises a discharge column clamped by a tension element 11 between two end fixtures 6,7. The electrical connection from the ground contact 3 to the high voltage contact 4 via the discharge element 5 from outside the housing 2 using the contact element 9 displaceable axially by the displacement device 8 Can be formed or blocked. According to the invention, the contact element 9 is guided in the bore 26 of the end fixtures 6,7. Thereby, the surge arrester 1 can be realized in a very small size. Moreover, the contact element 9 is guided in the bore 26 of the end fixtures 6, 7, thereby enabling a mechanically simple and reliable structure.

Description

Surge arrester {SURGE ARRESTER}

The present invention relates to a surge arrester according to the preamble of claim 1.

A surge arrester is a protection system, for example, for a switch, which protects other components of the switch by discharging such overvoltage to ground when an overvoltage occurs due to a malfunction of the lightning or other subsystem.

This type of surge arrester includes one or more cylindrical discharge elements, these discharge elements having a varistor column composed of individual varistor elements likewise cylindrical. The varistor device features a voltage-dependent resistance. At low voltage, the varistor element acts as an insulator. From a certain threshold voltage depending on the material, the varistor element exhibits good conductivity. The varistor element is mainly made from a metal oxide such as zinc oxide. The discharge element is limited at both ends by the end fixture which forms the electrical contact to the switchgear and ground. Also, in order to ensure good electrical contact under mechanical load, the varistor columns must be held together under pressure. This can be realized by clamping a tensile element, for example a cable or a rod, which is preferably made of glass fiber reinforced plastic, into the end fixtures. At this time, the tensile elements surround the varistor column and form a cage around the varistor column.

For use in a gas insulated switchgear, the surge arrester has a fluid-tight housing surrounding the discharge element. In this case, the housing is filled with a fluid, typically hexafluoride, to increase the dielectric strength. The housing is usually made of metal and electrically grounded. One end fixed body of the discharge column is grounded through a guided contact through the housing. The other end fixed body is located outside the housing and is electrically connected to the contact used for connection to the switch through a bushing.

If the switchgear is to be electrically tested, the surge arrester shall be disconnected from the switchge due to possible high voltage. Otherwise, the surge arrester can discharge the voltage to ground, and the measurement result may be distorted.

At present, there is known a surge arrester in which a surge arrester has a separating point from which the surge arrester can be separated from the switch. In order to operate such a separation point, the housing must be opened, thereby causing hexafluoride to escape. Hexafluoride is a harmful greenhouse gas, which is a very undesirable disadvantage.

From JP 10322822-A, a general-purpose surge arrester is known in which an assembly consisting of a discharge column and a control hood are moved together to form or block an electrical connection. Here, a linear movement is performed airtightly through the housing wall for operation.

International application PCT / EP2012 / 059973 describes a surge arrester in which the control hood can be displaced relative to the discharge element so that the break point can be opened or closed.

A disadvantage of the solutions known in the prior art is that a complex mechanism is required, a large mass must be moved, and a lot of space is required.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a small surge arrester having a simple mechanism having an externally operable breakaway point and as small a moving mass as possible.

The above problem is solved by means of the present invention according to claim 1.

The present invention provides a surge arrester having a fluid-tight housing. The housing has a ground contact and a high voltage contact, and the ground contact and the high voltage contact electrically connect the inside and the outside of the housing, respectively. The discharge element disposed in the housing has a discharge column clamped by a tension element between the two end fixtures. The electrical connection from the exterior of the housing to the high voltage contact through the discharge element through the discharge element can be formed or interrupted using a contact element displaceable axially by the displacement device. According to the invention, the contact element is guided in the bore of the end fixture. Therefore, the surge arrester can be formed very small. Also, the contact element is guided in the bore of the end fixture, thereby enabling a mechanically simple and reliable structure.

In one preferred configuration of the invention, the contact element is resiliently connected to the displacement device in the axial direction. Thereby, the longitudinal tolerance of the displacement device can be compensated in a simple manner without a complicated adjusting device.

It is also preferable that a plurality of, in particular three, discharge elements each having one contact element are arranged in the housing. In this case, the housing has one high-voltage contact for each discharge element, and the contact elements are jointly displaceable by the displacement device. Thereby, in a simple manner, it is possible to form a multipolar capsule type surge arrester having a separation point that is unique for each pole, but can be jointly manipulated.

 Particularly preferably, the displacement device has a push rod connected to the contact element for each discharge element. In addition, the displacement device includes a central rod that is guided outwardly from the inside of the housing to the outside and is movable by an operating device outside the housing. In this case, a coupling element is connected to the central rod and the push rod to transmit the movement of the actuating device to the contact element. Thereby, a plurality of separation points in the surge arrester can be very simply operated from the outside of the housing together with a single operating device.

Preferably, the central rod, together with the coupling element, forms a spindle driver for converting the rotational motion of the central rod into a linear motion of the coupling element. To this end, the central rod has a male thread portion and the coupling element has a corresponding female thread portion. Preferably, both of the two threads are trapezoidal threads. This enables a very simple and compact drive for the movement of the contact elements.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 is a cross-sectional view of a surge arrester according to the present invention in which a separation point is closed.
2 is a sectional view of a surge arrester according to the present invention in which a separation point is opened.
Figure 3 is a detailed view of the coupling element.
4 is a detailed view of the separation point.

Members that match each other have the same reference numerals in all figures.

1 and 2 show a cross section of the surge arrester 1. Three discharge elements (5) provided for protection of the three-phase gas insulated switchgear are arranged in the fluid-tight housing (2). The discharge elements 5 each have a cylindrical discharge column 12, a high voltage side end fixing body 7, a ground side end fixing body 6 and a plurality of tension elements 11. The discharge column 12 is likewise comprised of individual varistor blocks which are cylindrical in shape. The end holders 6 and 7 are usually formed of a conductive material. The tensioning elements 12 are squeezed in a tensioned state in the end fixtures 6, 7 to fix the discharge columns 12 together. A fixed disk 24 with perforated holes is inserted into the discharge column 12 and the tension elements 12 are guided through the holes to further stabilize the discharge element 5.

The housing 2 is substantially cylindrical. A longitudinal axis 50 defining an axial direction extends along the cylindrical axis. The discharge elements 5 are aligned along this longitudinal axis 50. The housing 2 is hermetically sealed in two cover surfaces.

The cover surface of the housing 2 is sealed by a simple housing cover 22 at one side of the ground connection side of the discharge element 5. The ground contact 3 is electrically insulated and passes through the housing cover 22 and is guided from the inside to the outside of the housing 2 to be used for ground connection. In the interior of the housing 2, the ground contact 3 is electrically conductive and connected to the discharge element 5, for example by means of a cable 13. The ground side end fixing body 6 is fixed to the housing cover 22 and is electrically insulated by the insulative insertion piece 25 with respect to the discharge column 12. [ The housing cover 22 typically has a connection, not shown here, through which fluid, e.g., hexafluoride, can be charged into the housing 2 or released from the housing. In addition, the housing 2 may have an additional device, such as a maintenance opening 21.

The cover surface of the housing 2 at the high voltage connection side of the discharge element 5 is provided with a conductive member for guiding the electric high voltage electric potential from the outside into the housing 2 without risk of flashover between the grounded housing 2 and the high voltage A high voltage bushing 14 is provided. Here, the bushing 14 is formed of a triode bushing 14 which guides three high-voltage contacts 4 insulated with respect to each other and to the housing 2 into the housing 2. Through the high voltage contacts 4, the surge arrester 1 can be connected to a three-phase gas insulated switch not shown here. In the interior of the housing 2, the high voltage contacts 4 project into the housing 2 in the form of fingers.

The gap between the high voltage side end fixture 7 and each high voltage contact 4 forms a separation point 10. This separation point 10 can be closed by the contact element 9. The contact element 9 is formed in a cylindrical shape as a pin or a sleeve and can move in the axial direction within the bore 26 of the high voltage side end fixing body 7. [ The bore 26 and the contact element 9 are then matched to one another so as to form a good electrical connection between the contact element 9 and the end fixture 7 as well as a mechanical guide. Alternatively, the electrical connection may be formed by a sliding contact. When the contact element 9 moves toward the high voltage contact 4, the separation point 10 is finally closed. The electrical connection from the switchgear to the interior of the housing 2 via the high voltage contact 4 is made via the contact element 9, the high voltage side end fixture 7, the discharge column 12, the ground cable 13, Finally, a grounded contact 3 is formed. When the contact element 9 moves away from the high voltage contact 4 the break point 10 is opened and the discharge element 5 is not connected to the switch as it is no longer electrically connected to the high voltage contact 4.

The movement of the contact element 9 is carried out by the displacement device 8. [ The displacement device has an actuating device 23, a central rod 16, a coupling element 17 and a push rod 15. An actuating device 23, which is external to the housing 2, is connected to a central rod 16 which is guided airtightly into the housing 2. The coupling element 17 is arranged on the center rod 16 inside the housing 2. [ The central rod 16 and the coupling element 17 are then formed such that the central rod 16 has a male threaded portion and the coupling element 17 has a corresponding female threaded portion such as a trapezoidal threaded portion to form a spindle- do. The coupling element 17 is provided with an arm 19 directed radially outward for each discharge element 5 and a connecting element 20 for receiving the push rod 15 is arranged at the outer end of the arm. Such a coupling element is shown in Fig. The push rod 15 is fixed within the connecting element 20 by one end thereof and is connected to the contact element 9 by the other end thereof. The connection of the push rod 15 and the contact element 9 is elastically realized as shown in Fig. To this end, the push rod 15 is inserted into the bore 30 of the contact element 9. The ring-shaped collar 33 forms a stop for the spring 32, which is formed here as a helical spring, which is fitted to the end of the push rod 15. The shoulder at the point where the bore 30 transitions to the wider diameter bore 31 forms an additional stop for the spring 32. The end of the bore 31 is closed by a stopper 34 through which the push rod 15 passes. The stopper 34 prevents the pushrod 15 from falling out of the bore 31. When the contact element 9 is moved close to the high voltage contact 4 by the push rod 15, that is, when the push rod 15 further moves in the direction of the high voltage contact 9, Tension between the collar 33 and the shoulder between the contact elements 9,30,31 and the high pressure contact 4 with respect to the contact element 9.

When the actuating device 23 rotates, the pull rod 16 rotates inside the housing 2 and the rotational motion of the actuating device 23 is transmitted to the push rod 15 and the contact element 9 ). At this time, the separation point 10 is opened or closed depending on the direction of motion.

Claims (5)

A surge arrester (1) comprising a fluid-tight housing (2) having a ground contact (3) and a high voltage contact (4) and a discharge element (5) disposed in the fluid-
The ground contact 3 and the high voltage contact 4 electrically connect the inside of the housing 2 to the outside respectively and the discharge element is connected to the tension element 11 between the two end holders 6, (3) to the high voltage contact (4) via the discharge element (5) by means of a contact element (9) displaceable axially by the displacement device (8) Can be formed or shut off,
The contact element 9 is guided in the bore 26 of the end fixtures 6,7,
A plurality of discharge elements 5 each having one contact element 9 are arranged in the housing 2 and the housing has one high voltage contact 4 for each discharge element 5, Characterized in that the contact elements (9) are displaceable by the displacement device (8). 2. Surge arrester (1) according to claim 1, characterized in that the contact element (9) is resiliently connected to the displacement device (8) in the axial direction. delete The displacement device according to claim 1, characterized in that for each discharge element (5), a push rod (15) connected with the contact element (9) Each having a central rod 16 which is moveable by means of an actuating device 23 on the outside of the central rod 16 and the push rod 15 in order to transmit the movement of the actuating device 23 to the contact element 9. [ Characterized in that a coupling element (17) is connected to the output of the surge arrester (1). 5. A device according to claim 4, characterized in that the central rod (16) forms a spindle drive with a coupling element (17), which converts the rotational motion of the central rod (16) into a linear motion of the coupling element (1). ≪ / RTI >

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