DE4205501C1 - High tension switch preventing arcing when switched off - has two slidable contacts surrounded by insulating nozzle during on state, and control electrode surrounding nozzle. - Google Patents

Abstract

The HT switch has two slidable contacts (5,6) facing one another, respectively equipped with rated current contacts(8,9). An insulating nozzle (10) fixed at one of the contacts (6) surrounds the contacts in the switched-on position. The rated current contacts are isolated from the slidable contacts (5,6) during the switch-off, and in the switched-on position they are arranged between the nozzle and a switching chamber housing (1) surrounding the switch. The insulating nozzle exhibits at least one circular conducting zone (11), at one of its end region, when the HT switch is in an open position. At least one control electrode (12) is provided, acting as a counter electrode to the conducting zone and encircling the nozzle at a distance when the switch is switched-on. ADVANTAGE - Arc-back caused by unfavourable field distribution at switch-off is prevented.

Description

The invention relates to a high voltage switch according to the Preamble of claim 1.

Such a high-voltage switch is known from the company brochure of AEG Aktiengesellschaft with the title "SF ₆ power switch. 72.5-765 kV", A22V.7.61 / 0 286 DE / EN; it has a switching chamber with a fixed and a movable contact piece. When switching off, an arc arises between the contact pieces. An insulating material nozzle is connected to the movable contact piece and laterally surrounds both contact pieces in the switched-on position. In the switch-on position, the current flows both via the contact pieces and via a fixed nominal current contact, which in the switch-on position is applied to a conductive compression cylinder connected to the movable contact piece.

The invention has for its object by constructive Measures with a high voltage switch an unfavorable To avoid field distribution inside, caused by a accumulation of free charge carriers when switched off on the insulating material nozzle when switching off capacitive currents Could cause reignition.

This task is solved by a high voltage switch Claim 1.

On the field distribution inside the high-voltage switch immediately after switching off a capacitive current favorable from that the insulating nozzle with a conductive zone This conductive zone prevents the Course of a switch-off process on the insulating nozzle Charging accumulated free charge an electric field cause what could favor the reignition of the arc.  

The conductive zone on the insulating material nozzle ensures quick Distribution of free charge carriers.

Without this zone, the resulting charge distribution would only degrade relatively slowly, leading to undesirable flashbacks of the arc.

A high-voltage switch is to disconnect a line from the network. A such a line has - with a simplified view of the Switching operations - the effect of a capacity. If the stream leads the voltage by 90 degrees, is at a current zero crossing just the maximum voltage on the line. When switching off in Current zero crossing remains due to the capacitive (storage) effect of the Line received this voltage for a relatively long time. If the generator originating mains voltage half a period later (i.e. after 10 ms at a frequency of 50 Hz) their maximum value in reversed polarity is between the contacts a voltage (return voltage) that is greater than the peak value of the mains voltage. Up to this point must go through sufficient distance between the contact pieces Dielectric strength of the switch must have risen so far that it does not reignite. Significant problems can arise with quickly repeated switching or short interruption switching occur; these problems can be avoided by constructive measures, preferably through a conductive area at the insulating material nozzle, a concentrated accumulation of Load carriers in narrowly defined areas of the insulating material nozzle is prevented.

Further advantageous embodiments of the invention are the rest See subclaims.

The invention is described below with the aid of a figure illustrated embodiment, from which further features, Details and advantages result, described in more detail.

Show it

Fig. 1 shows the section through a high-voltage switch with a conductive coating on the moving with the movable switching element insulating material nozzle and with a fixed control electrode and

Fig. 2 shows the section through a high-voltage switch with other embodiments of the control electrode.

In Fig. 1, a high-voltage switch is shown in section, which has an insulating interrupter housing ( 1 ) - preferably made of porcelain - in which there is a vertically arranged conductive sleeve ( 2 ) with an attached, from the interrupter housing ( 1 ) lead contact piece located. The interrupter housing ( 1 ) is filled with a protective gas (SF ₆ ). In the lower part of the sleeve ( 2 ), a fixed contact ( 5 ) is attached to a metal support ( 4 ), which is only in conductive connection with a movable contact ( 6 ) when the high-voltage switch is closed. The movable contact piece ( 6 ) is arranged in a contact carrier ( 7 ) which can be moved together with it. At the lower end of the sleeve ( 2 ) there is a nominal current contact piece ( 9 ) which, in the switched-on position of the high-voltage switch, touches another nominal current contact piece ( 8 ) belonging to the displaceable contact carrier ( 7 ) and carries a considerable part of the current when the high-voltage switch is closed.

Connected to the sliding contact carrier ( 7 ) is an insulating nozzle ( 10 ) protruding from the top, which surrounds both switching elements ( 5 , 6 ) laterally in the switch-on position and within which an arc that arises between the two switching elements ( 5 , 6 ) when switched off extends. In the upper area of the outer surface of the insulating material nozzle ( 10 ) there is a planar conductive zone ( 11 ) in the form of a closely fitting, conductive metal sleeve. Opposite the circumference of this metal sleeve, a conductive control electrode ( 12 ) running around the inside of the sleeve ( 2 ) can also be attached, as shown in the left half of FIG. 1. The control electrode ( 12 ) can protrude downward over the lower edge of the sleeve ( 2 ). It is also possible to arrange several control electrodes next to one another on the inside of the sleeve ( 2 ). Instead of using a separate construction part as a control electrode ( 12 ), it is also possible to design it in its lower region by appropriately shaping the sleeve ( 2 ).

When switching off, the movable contact piece ( 6 ) is moved down with the help of a drive. A drive rod ( 13 ) transmits the movement to the switching element. When capacitive currents are switched off, there is a constant change in the field distribution within the high-voltage switch - especially if the interruption occurs very shortly after switching elements ( 5 ) and ( 6 ) are separated - caused on the one hand by the change in the mains voltage over time and on the other by Movement of the contact pieces ( 5 , 6 ) to each other. In one position of the contacts (5, 6) according to Fig. 1, the field distribution is substantially on the area between the contact pieces (5, 6) are concentrated and between the rated current contact pieces (8, 9).

A lack of the conductive zone ( 11 ) would have considerable disadvantages for the dielectric strength of the high-voltage switch: If the fixed contact ( 5 ) is connected to a high-voltage line and is consequently not exposed to AC voltage after the arc has been extinguished, the insulating nozzle ( 10 ) would the free charge carriers initially remain at the point at which they have accumulated.

In the worst case, the charge carriers could still be one previous switch-off process may be present in some places, if the next switch-off is already taking place. Now kick that Add this field to this subsequent deactivation, so can certain points increase the field strength so much that it becomes a Backfire causing discharge occurs.

In the absence of a conductive zone ( 11 ) on the insulating material nozzle ( 10 ) and without a control electrode ( 12 ), the electrical field in the switch-off position would protrude far into the interior of the sleeve ( 2 ); in the vicinity of the contact pieces ( 5 , 6 ) the field strength would be quite large. In comparison, in the case of a conductive zone on the insulating material nozzle ( 10 ) and when a control electrode ( 12 ) is installed, the electrical field is concentrated on the central part of the insulating material nozzle ( 10 ). As a result, the charge carriers accumulate in this part of the insulating nozzle ( 10 ); this area is not in the immediate area of the contact pieces ( 5 , 6 ) in the off position. The risk of reignition is therefore reduced. The conductive area and the control electrode prevent the penetration of a large field into the sleeve ( 2 ) and the creation of a high field strength in the immediate vicinity of the contact pieces ( 5 , 6 ). These considerations could be clearly derived from the density of the equipotential lines in a sectional view of the high-voltage switch. The conductive zone ( 11 ) and the control electrode ( 12 ) influence the course of the equipotential lines; the conductive coating prevents several equipotential surfaces from running closely together through the upper part of the insulating material nozzle ( 10 ). As a result, there is a correspondingly low electrical field strength compared to a high-voltage switch without control electrodes and conductive coating.

The conductive zone ( 11 ) together with the control electrode ( 12 ) or - if there is no control electrode ( 12 ) - with the mating contact sleeve ( 2 ) or with the rated current contact piece ( 9 ) forms a capacitance that changes during a switch-off process. This change in capacity entails a change in the field distribution; on the one hand it causes a displacement current and on the other hand a current flow is generated in the conductive zone ( 11 ) and in the control electrode ( 12 ). This prevents the build-up of a static field in and on the insulating material that is dangerous for reignition.

If the conductive area-like zone ( 11 ) and the control electrode ( 12 ) are arranged at an angle to one another, a rather rapid change in the capacitance is brought about in the course of the switch-off movement, which results in a particularly rapid distribution of the charge carriers.

The conductive zone ( 11 ) can also be realized by an externally applied conductive plastic layer instead of an attached metal sleeve. Instead of placing the conductive zone ( 11 ) on the outside, it is also possible to arrange it inside the insulating material nozzle ( 10 ). Likewise, the upper part of the insulating material nozzle can be made entirely of a conductive material. In all these cases it is achieved that the charge carriers are distributed very quickly and, as a result, re-ignition due to an excessive electric field strength is avoided.

Fig. 2 shows a longitudinal section through a high-voltage switch which, except for the design and position of the control electrodes ( 12 a, 12 b) attached to the inside of the sleeve ( 2 ), corresponds to the high-voltage switch according to FIG. 1. The same parts as in Fig. 1 are given the same reference numerals. Fig. 2 illustrates two ways of attaching a control electrode ( 12 a, 12 b) inside the sleeve ( 2 ), namely in the left half of the picture is a narrow, strip-shaped around the inside of the sleeve ( 2 ) control electrode ( 12 a ). There is a small distance between the control electrode ( 12 a) and the lower end of the sleeve ( 2 ); the control electrode ( 12 a) is electrically insulated from the sleeve ( 2 ). In the right half of the picture, a narrow, strip-shaped control electrode ( 12 b) is shown, the upper edge of which is attached to the lower edge of the sleeve ( 2 ), so that the control electrode ( 12 b) in the switch-off position shown between the conductive zone ( 11 ) and the Nominal current contact piece ( 9 ) of the fixed contact piece ( 5 ) is arranged. There is no conductive connection between the control electrode ( 12 b) and the sleeve ( 2 ).

Basically, the field control can also be influenced by a capacitive coupling of the control electrode ( 12 , 12 a, 12 b) to the sleeve ( 2 ). For this purpose, the control electrode ( 12 ) is attached to the sleeve ( 2 ) at a distance and the distance is filled by an insulator with a suitable dielectric constant, which means that the field shape is significantly determined. With this capacitive coupling, care must be taken that the loss factor of the insulating material is so large that the capacitance discharges in the time between two circuits. Since the capacity is very small, this is easily possible.

Of course, it must always be ensured when arranging the control electrodes ( 12 , 12 a, 12 b) and the conductive zone ( 11 ) that the high-voltage switch withstands the requirements for dielectric strength at the required test voltages during the switch-off process. This means that the permissible distance between the control electrodes ( 12 , 12 a, 12 b) and the conductive zone ( 11 ) must not be undercut and that the edges of the control electrodes ( 12 , 12 a, 12 b) must be shaped in such a way that that the field strengths do not become impermissibly high there.

Claims (9)

1.High-voltage switch with two mutually displaceable contact pieces, each equipped with at least one nominal current contact piece and with an insulating nozzle surrounding the contact pieces laterally in the switch-on position and attached to one of the contact pieces, whereby an arc forms between the contact pieces when current is interrupted, the nominal current contact pieces during separate the switching off in time before the switching pieces and are arranged in the switch-on position between the insulating nozzle and a switching chamber housing surrounding the high-voltage switch, characterized in that the insulating nozzle ( 10 ) has at its one end region which, when the high-voltage switch is open, is not connected to the insulating nozzle ( 10 ) Switch piece ( 5 ) is closest, has at least one circumferential, conductive zone ( 11 ). 2. High-voltage switch according to claim 1, characterized in that non-displaceably to the switching piece ( 5 ) not connected to the insulating material nozzle ( 10 ), there is at least one control electrode ( 12 , 12 a, 12 b) within the switching chamber housing ( 1 ), which in the Switch-on position of the high-voltage switch is circumferentially arranged at a distance around the insulating material nozzle ( 10 ). 3. High-voltage switch according to claim 2, characterized in that the switching piece ( 5 ) which is not connected to the insulating nozzle ( 10 ) is arranged in a sleeve ( 2 ) surrounding the switching piece and that the control electrode ( 12 , 12 a, 12 b) is connected to the Inner surface of the sleeve ( 2 ) is attached. 4. High-voltage switch according to claim 3, characterized in that the control electrode ( 12 , 12 a, 12 b) is arranged at a distance from the sleeve ( 2 ) and that the distance between the sleeve ( 2 ) and control electrode ( 12 , 12 a, 12 b) is filled with an insulating material. 5. High-voltage switch according to one of claims 2 to 4, characterized in that the conductive zone ( 11 ) and the opposite control electrode ( 12 , 12 a, 12 b) are flat and arranged at an angle to each other. 6. High-voltage switch according to one of the preceding claims, characterized in that the conductive zone ( 11 ) consists of a conductive plastic. 7. High-voltage switch according to one of the preceding claims, characterized in that the conductive zone ( 11 ) is designed as a covering arranged on the insulating nozzle ( 10 ). 8. High-voltage switch according to one of claims 1 to 6, characterized in that the conductive zone ( 11 ) is in the interior of the insulating nozzle ( 10 ). 9. High-voltage switch according to one of claims 1 to 5, characterized in that the conductive zone ( 11 ) is formed by a metal sleeve which the end region of the insulating nozzle ( 10 ), which when the high-voltage switch is open, the contact piece not connected to the insulating nozzle ( 10 ) ( 5 ) is closest, closely fitting on the outside.