KR20140012164A - Surge arrestor - Google Patents

Abstract

The present invention relates to an electric discharge machine comprising a discharge member 20, a control cowl portion 40 electrically connected to the discharge member 20, a discharge member 20 and a control cowl portion 40 disposed therein, (2) having two contacts (7, 8) for electrically connecting the outside and the inside, respectively, to the overvoltage circuit breaker (1). The discharge member 20 and the control cowl portion 40 are formed so as to be relatively movable with respect to each other, and through the relative movement, the contacts 7 and 8 on one side of the contacts are connected to the contacts 20, An overvoltage circuit breaker is provided which enables a structurally simple formation or interruption of the electrical connection by making or breaking an electrical connection to the contacts 8, 7 on the other side.

Description

Overvoltage breaker {SURGE ARRESTOR}

The present invention relates to an overvoltage circuit breaker according to the preamble of claim 1.

Overvoltage breakers are protection systems for switching systems that protect other components of the switching system by discharging the overvoltage to ground, for example, when an overvoltage occurs through the failure of a lightning stroke or other subsystems.

The overvoltage breaker of this type comprises at least one cylindrical discharge member with a varistor column, which is likewise made up of cylindrical varistor elements. The varistor members are characterized by a voltage-dependent resistance. When the voltage is low, the varistor members function as an insulator. From the specific threshold voltage depending on the material, the varistor elements exhibit good conductivity. Usually, the varistor members are made of a metal oxide such as zinc oxide. The discharge member is limited at both ends of an end fitting that forms electrical contacts to the switching system and ground. To ensure good electrical contact under mechanical load, the varistor column must be clamped under pressure. This can be done by tensioning the tension members, e.g. ropes or rods, preferably glass fiber reinforced plastic material, under tension in the end fittings. In this case, the tension members surround the varistor column to form a cage around the varistor column.

The overvoltage circuit breaker includes a liquid tight housing surrounding the discharge member for use in gas insulated switching systems. In this case, the housing is filled with a fluid, usually sulfur hexafluoride, to increase the insulation strength. The housing is usually made of metal and electrically grounded. One end fitting of the discharge column is grounded through a contact which is guided through the housing. The other end fitting is electrically connected via a feed-through to a contact located on the outer surface of the housing and serving as a connection to the switching systems. Particularly larger overvoltage circuit breakers typically include a control cowl at the high voltage side end, and the control cowl portion is overlaid over the end of the discharge column as a closed cylinder on one side. Although individual varistor members have a high capacitance with respect to ground potential, the series circuit of individual varistor members results in very small longitudinal capacitance, which results in non-uniform voltage distribution from a given installation length of the varistor column. Thus, the varistor members are subjected to a relatively higher load depending on the voltage at the portion of the varistor column that is farther from the ground potential, which can lead to unintended heating with resistive action. On the other hand, the control cowl portion is used to equalize the voltage distribution along the length of the varistor column.

If an electrical inspection of the switching system is required, the overvoltage breaker must be disconnected from the switching system due to the high voltage at this time. Otherwise, the overvoltage breaker may discharge the voltage to ground and the measurement result may be distorted.

Up to now, an overvoltage breaker including a disconnected position is known, whereby the overvoltage breaker can be disconnected from the switching system. For the operation of the separation position, the housing must be opened, so that sulfur hexafluoride can flow out. Because sulfur hexafluoride is a harmful greenhouse gas, its release is the least desirable and therefore undesirable.

JP 10322822-A discloses a general overvoltage circuit breaker in which an assembly consisting of a discharge column and a control cowl unit is moved together to form or interrupt electrical connection, thereby separating the discharge column from the switching system. In this case, for operation, the airtightly linear movement is performed through the housing wall portion.

An object of the present invention is to provide an overvoltage circuit breaker which is structurally simple to form or break the electrical connection in the overvoltage breaker of the type mentioned at the beginning.

The above problem is solved by a common overvoltage circuit breaker comprising the features specified in the characterizing part of claim 1.

In this case, according to the present invention, there is provided a discharge lamp comprising a discharge member, a control cowl portion electrically connected to the discharge member, a discharge member and a control cowl portion disposed therein, and two contact points electrically connecting the outside and the interior of the housing, respectively There is provided an overvoltage circuit breaker including a liquid tight housing. At the same time, the discharge member and the control cowl portion are formed so as to be relatively movable with respect to each other, and through the relative movement, an electrical connection is made to the contact of the other one of the contacts via the discharge member at one of the contacts, . Through the relative movement of the control cowl and the discharge member, electrical connection can be made or interrupted for the switching system in a particularly simple manner. For example, the control cowl portion and the discharge member can be moved together, for example, in various directions. Alternatively, the control cowl portion may be fixedly seated and only the discharge member may be moved. In any case, since the mass to be moved is smaller than in the prior art, the mechanical members necessary for the movement can be structurally simple to implement.

According to one preferred embodiment of the overvoltage circuit breaker according to the invention, the discharge member is disposed along the longitudinal axis of the housing and the control cowl portion is arranged displaceably in the longitudinal direction. This provides a particularly compact arrangement. The displacement of the control cowl portion along the longitudinal axis enables the formation and termination of the electrical connection to the switching system, while maximizing the compliance of the required insulation spacing and space utilization.

According to a further preferred embodiment of the overvoltage circuit breaker according to the invention, the control cowl portion can be displaced by a displaceable device actuable from the outside of the liquid-tight housing. Thereby, the electrical connection of the discharge member with respect to the switching system can be formed and interrupted, preferably under the condition that the housing is closed. Therefore, the opening of the housing and the gas loss associated therewith can be prevented.

Particularly preferably, the overvoltage circuit breaker according to the present invention is characterized in that the overvoltage circuit breaker according to the present invention comprises a shaft which can be actuated by rotational motion, a push rod connected to the control cowl portion, a gear for converting the rotational motion of the shaft into a translational motion of the push rod, Device. ≪ / RTI > The displacement device is particularly compact and permits simple operation. The pivoting portion of the shaft guided inward of the housing is simply sealed through the associated action.

According to another preferred embodiment of the overvoltage circuit breaker according to the present invention, the push rod is at least partially composed of an electrically insulating material. It may be, for example, glass fiber reinforced plastic. Therefore, the insulation strength is preferably ensured because flash-over is prevented between the push rod and the housing.

According to a further embodiment of the overvoltage circuit breaker according to the invention, the shaft is guided from the interior to the exterior of the housing in a liquid-tight manner. This prevents the outflow of fluid from the housing. Harmful environmental effects through the fluid are thus prevented. In addition, the withstand voltage is maintained, and thus the maintenance of the overvoltage circuit breaker is less required.

According to a preferred embodiment of the present invention, one end of the discharging member is electrically connected to one of the contacts and the other end of the discharging member is electrically connected to the control cowl, and through the displacement of the control cowl, An electrical connection may be formed or interrupted for the other contact. This allows only the control cowl portion to be moved for connection formation and interception. The control cowl portion is relatively light as compared with the discharge member. Therefore, the movement of the control cowl portion requires less mechanical complexity.

According to a further preferred embodiment of the overvoltage circuit breaker according to the invention, the control cowl and the other one of the contacts are arranged in a radially fixed manner in relation to the longitudinal axis when an electrical connection is formed, All. This allows the control cowl and contacts to be centered and tilted relative to each other when the contacts are closed. By forming the control claw portion and the contact with reflection symmetry, the largest possible contact surface can be created between the control claw portion and the contact point. This ensures a reliable connection of the control cowl portion to the high voltage potential of the contact.

Further, preferably, the control cowl portion can be connected to the discharge member via sliding bearings for the satellite in the vertical axis direction. Preferably, the sliding bearings are mounted to the end electrodes at the side, and guide and fix the control cowl portion in the radial direction with respect to the longitudinal axis. Further, when an electrical connection is formed, the control cowl portion is fixed radially through the contact. Further, if the ground-side end of the discharge member is fixed in the radial direction, for example, through fixed engagement of the housing cover and the ground-side end electrode, the discharge member and the control cowl portion are fixed to each other with respect to the housing, It becomes.

The invention will now be described in more detail with reference to the drawings.
1 is a sectional view showing an overvoltage circuit breaker with an electrical connection interrupted.
2 is a cross-sectional view showing an overvoltage breaker in a state in which an electrical connection is formed;
3 is a cross-sectional perspective view showing a portion of FIG.

In the drawings, corresponding members are denoted by the same reference numerals.

In Figs. 1 and 2, an over-voltage circuit breaker 1 is shown in a sectional view. A discharge member (20) is disposed in the liquid-tight housing (2). The discharge member 20 includes a cylindrical varistor column 25, an upper end fitting 22, a lower end fitting 21, and a plurality of tension means 23. The varistor column 25 is likewise comprised of individual varistor blocks of cylindrical shape. End fittings 21 and 22 are seated on both ends of the varistor column 25, and only the lower end fitting 21 is visible in FIGS. The end fittings 21, 22 are usually constructed of an electrically conductive material. The tension members 23 are compressed under tension into the end fittings 21, 22 and thereby bind the varistor column 25. Inside the varistor column 25 are fitted grasping discs 24 with holes through which the tension members 23 are guided and further stabilize the discharge member 20.

The housing 2 is substantially cylindrical. The longitudinal axis 50 extends along the cylindrical axis. The discharging member 20 is oriented along the longitudinal axis 50. The housing 2 is sealed in a liquid-tight manner on both cover surfaces.

The cover surface of the housing 2 on the ground connection side of the discharge member 20 is sealed by the simple housing cover 4. [ The contact 8 is electrically insulated through the housing cover 4 and guided from the inside to the outside of the housing 2, and is used as a ground connection part. Inside the housing 2, the contact 8 is connected to the discharge member 20 in an electrically conductive manner, for example with a cable 15. Here, the connection is carried out through the conductive connecting plate 13. An insulating connecting piece (14) is positioned between the connecting plate and the lower end fitting (21). The connection of the cable 15 can alternatively be performed directly on the lower end fitting 21, in which case the insulating connection piece 14 is omitted. The end fitting 21 of the discharge member 20 is fixed to the housing cover 4. [ The housing cover (4) is electrically insulated against the varistor column (25). Here, the insulation is carried out through the connecting piece 14. Alternatively, an insulating layer may be sandwiched between the lower end fitting 21 and the housing lid 4. Typically, the housing lid 4 comprises a port not shown in the drawing, through which fluid, in particular sulfur hexafluoride, can be filled into or discharged from the housing 2.

On the cover surface of the housing 2 on the high-voltage connecting side of the discharge member 20, a high-voltage (high-voltage) power supply for guiding the electric high-voltage electric potential from the outside to the inside of the housing 2 without danger of flashover between the high- A feed-through 5 is provided. The feedthrough 5 includes a grip ring 12, an insulator 6, and a contact 7 implemented as a plug-in contact in this case. The over-voltage circuit breaker 1 can be connected to the gas-insulated switching system not shown in the figure via the contact 7. Inside the housing 2, the contact 7 is provided with an electrically conductive fitting 9. At the contact surfaces for the housing 2 and the switching system, the feed-through is provided with sealing rings 10.

The control cowl portion (40), which is substantially cylindrical and has one end closed, is covered over the high voltage side end portion of the discharge member (20). The control cowl portion 20 is connected to a displacement device 30 which comprises a push rod 33 and a gear device 32 which can be embodied for example as a trapezoidal worm gear and a housing cover 4 And an operating member 34 connected to the shaft 31 at the outside of the housing 2. The shaft 31 includes a shaft 31, In addition, the operating member 34 may be equipped with a display device 35 indicating whether or not the electrical connection is formed or interrupted.

The shaft 31 can be converted into rotational motion, via the actuating member 34 shown as a handwheel in the figure. The rotational motion is converted to linear motion of the push rod 33 in the direction of the longitudinal axis 50 via the gear device 32. The push rod 33 again transmits the linear movement to the control cowl portion 40. For better guidance of the push rod 33, the push rod is guided through the holes in the grasping discs 24. Thus, the control cowl 40 can be moved closer to or away from the contact 7 in the direction of the longitudinal axis 50, whereby electrical connection can be made or interrupted. 1 shows a state in which the electrical connection is interrupted.

In Fig. 2, the control cowl portion 40 is moved toward the contact 7 until the contact portion contacts the control cowl portion. Thereby, an electrical connection is formed. Therefore, the contact 7, the control cowl portion 40, the discharge member 20 electrically connected to the control cowl portion 40, and finally the discharge member 20, There is a continuous electrical connection from the electrically connected contacts 8 to the outside surface of the housing 2 on the ground side.

In Figure 3, a portion of the high-voltage side end of the over-voltage circuit breaker 1 is shown in a cross-sectional view. Here, an electrical connection is formed. The control cowl portion (40) is adjacent to the fitting (9) of the contact (7). The control cowl portion 40 and the fitting 9 are formed such that the projection of the fitting 9 is engaged into a corresponding depression of the closed end of the control cowl portion 40. [ Thus, the control cowl portion 40 is fixed radially with respect to the longitudinal axis 50.

The end fitting 22 includes sliding bearings 41 that secure the control cowl portion 40 in a radial direction relative to the longitudinal axis 50 and which, when displaced in the direction of the longitudinal axis 50, Guides the wool portion 40. The sliding bearings 41 can be implemented electrically and can be used for electrical connection of the end fitting 22 and the control cowl portion 40 at the same time, but the sliding bearings can also be made of a nonconductive material such as plastic . Then, the electrical connection between the control cowl portion 40 and the end fitting 22 can be performed, for example, through a flexible strip conductor.

Claims (9)

And a control cowl portion (40) electrically connected to the discharge member (20), wherein the discharge member (20) and the control cowl portion (40) are disposed inside the discharge member (20) (2) having two contact points (7, 8) for electrically connecting the two contacts (7, 8), respectively, in the overvoltage circuit breaker (1)
The discharge member 20 and the control cowl portion 40 are formed so as to be movable relative to each other and move relative to each other through one of the contacts 7 and 8 of the contacts via the discharge member 20, Characterized in that an electrical connection can be made or interrupted for the contacts (8, 7). The overvoltage circuit breaker according to claim 1, characterized in that the discharge member (20) is arranged along the longitudinal axis (50) of the housing and the control cowl section (40) is displaceably arranged in the longitudinal axis One). The overvoltage circuit breaker (1) according to claim 2, characterized in that the control cowl portion (40) can be displaced by a displacement device (30) which can be actuated from the outside of the liquid tight housing (2). 4. The apparatus according to claim 3, wherein the displacement device (30) comprises a shaft (31) which can be actuated by a rotational motion, a push rod (33) connected to the control crawler section (40) Characterized in that it comprises a gear device (32) which converts into translational motion of the rod (33). 5. An overvoltage circuit breaker (1) according to claim 4, characterized in that the pushrod (33) is at least partly constructed of an electrically insulating material. The overvoltage circuit breaker (1) according to claim 4 or 5, characterized in that the shaft (31) is guided from the inside to the outside of the housing (2) in a liquid-tight manner. 7. The discharge end of the discharge member 20 is electrically connected to one of the contacts 7 and 8, and the other end of the discharge member 20 is connected to the control cowl. Over-voltage circuit breaker (1), which is electrically connected to (40), characterized in that an electrical connection can be made or interrupted to the other of the contacts (8, 7) via a displacement of the control cowl (40). 8. The electrical connector according to claim 7, characterized in that the control cowl portion (40) and the other one of the contacts (8,7) are arranged in a radially fixed relation with respect to the longitudinal axis (1). ≪ / RTI > 9. The overvoltage circuit breaker (1) according to claim 8, characterized in that the control cowl portion (40) is connected to the discharge member (20) via slide bearings (41) for longitudinal satellite.

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