SE534914C2 - Single phase insulation consisting of air insulation and screens - Google Patents

Abstract

High-voltage switchgear comprising vacuum switches-type circuit breakers (2) and disconnectors (7) arranged one above the other in a single-phase insulated design. Operating shafts (3, 9) are arranged for the circuit-breaker and the disconnector, respectively. Two different types of single-phase oiling are used for the circuit breaker and disconnector unit and for phase lines emanating from the power plant (8). The single-phase insulation consists of | uftiso | e-ring and screen walls (6) for the circuit breaker and disconnector unit (2, 7) and waste material, preferably shrink plastic (14), on the surface of the outgoing phase line (8). (Fig. 1)

Description

30 534 914 2 means, in order to better and faster than with a pure air insulation be able to extinguish occurring arcs, mainly in connection with a refraction of high effects and high alternating currents and under high voltage. SF6 also has better insulating properties, which is used to get shorter insulating distances. However, SF6 gas is a greenhouse gas and therefore requires cumbersome and expensive handling, not only because it requires the use of a gas-tight container or tank but also because it contributes negatively to the greenhouse effect.

In addition, this gas has been shown to cause, from a corrosion point of view, aggressive residual products during each mining process.

Various other constructions of circuit-breaker units are also previously known, such as such constructions when a formed electric arc can be extinguished by means of a directed strong air flow or air shock, set under a high overpressure. and with the air current or shock directly directed to the spread and length of the expected arc. This of course means extra equipment that complicates and makes the construction of the switchgear more expensive.

It is also previously known that in the case of switchgear for 3-phase networks, each of the individual and voltage-emitting conductors emanating from the switchgear is single-phase in such a way that any occurrence can only occur between one of these phases and earth potential and never directly between the phases. . This proved to require a complex geometric design of the parts used and very bulky constructions within the switchgear.

It can also be mentioned that it is per se previously known that a generated negative pressure (vacuum) of an air volume encloses a breaking point in order to help reduce the construction of and / or the effect of an arc over the breaking point and also contribute to be able to extinguish the tendency of an formed arc. These so-called vacuum circuit breakers are insulated in known designs with a complicated shape on solid insulation.

The solid insulation is often epoxy casting resin. Baking a complex geometry with moving parts in epoxy is a very expensive solution.

In summary, it can be stated that known switchgear required space-consuming and / or complicated constructions and / or the use of substances that are less suitable from an environmental point of view, such as transformer oil, SF6 gas and the like. The object of the present invention is to provide a switchgear where the above-mentioned disadvantages are eliminated and an air-insulated compact switchgear is obtained.

This task has been solved by using two different types of single-phase insulation for the circuit breaker and fringe separator unit and for the phase lines emanating from the lower side of the switchgear.

In this way, the switchgear can be arranged independently of the atmosphere surrounding the switchgear. This is achieved in particular in that the single-phase insulation for the circuit breaker and fringe separator unit consists of air insulation.

The single-phase insulation of the phase line extending on the lower side of the switchgear consists of artificial material, preferably of shrink plastic applied to the phase line.

Thanks to simple geometry, your types of insulating layers can be applied. As an alternative to shrink plastic, you can, for example, dip the conductors in thermosetting or thermoplastic. Another alternative is to varnish the conductors with fl your layers.

In this context, the circuit breaker included in the circuit breaker and isolator unit refers to a circuit breaker which can break currents of at least 2000 A and which does not require e.g. SF6 gas as switching medium or insulating medium. Therefore, a vacuum switch or other circuit breaker known per se is advantageously used which is compact without requiring SF6 gas as the breaking medium or insulating medium. This entails, among other things, a significant saving of space.

With a construction according to the invention where the circuit breaker and separator unit is housed in a space, where air of atmospheric pressure forms the single-phase insulation and where the space is separated from the part of the switchgear from which the phase line originates, a significant advantage is achieved. in the desired direction independent of the direction of the circuit breaker and disconnect unit actuators.

The separation of the space with the circuit breaker and fringe separator unit from the lower side of the switchgear with the outgoing phase line located there, advantageously consists of an electrically conductive bottom beam connected to earth. Several bottom beams together form a grounded mezzanine floor. In particular, if this bottom beam is part of the switchgear's compartment or cabinet construction, a well-accessible surface is obtained for preparing the disconnector in its switch-off position.

The separating bottom beam advantageously carries a phase penetration of suitable electrically insulating material, such as thermoplastic which is glass fi-reinforced (which is a significantly cheaper solution than conventional penetrations of casting resin, epoxy, etc.) used hitherto). The conductor emanating from the circuit breaker and disconnector unit can be directly connected to the plastic-insulated phase line on the lower side via the phase bushing. By designing the phase bushing with a creep distance, any contaminants of the air insulation, such as moisture, salinity, dust particles and the like, can be taken into account.

When designing the switchgear for three-phase systems, the phases in the space for the circuit breaker and disconnector unit are separated from each other by an electrically insulating wall. This ensures that an overshoot and an arc formation are effectively prevented between the phases. Since the single-phase insulation for the circuit breaker and disconnector unit consists of air insulation, no pressure relief is required for the tank in which the switchgear is housed, as the single-phase insulation avoids arcing between the phases.

By arranging the circuit breakers in the three-phase system in line with each other, whereby the respective associated disconnectors are also in line with each other, a well-suited stretch for the respective control shaft for the circuit breakers and the disconnectors is achieved.

These control shafts are advantageously parallel to each other and are arranged to be manually operated.

By grounding the control shafts, they can penetrate the walls that separate the phases without the requirement for tightness. An imaginary arc always hits earth before it can reach another phase.

The hand-independent maneuvering of the switching on and off of the control shafts is triggered by tar and takes place with the help of capercaillie forces acting on the control shafts.

Thus, for example, the control shaft of the disconnectors may comprise or consist of a torsion spring, with whose spring force connection and / or disconnection takes place.

With the switchgear according to the invention, since the single-phase insulation on the circuit breaker and disconnector unit cable consists of air insulation of atmospheric pressure, a very advantageous opportunity to expand the switchgear by connecting your switchgear wall to wall is obtained. Suitable openings are then accommodated in the switchgear wall and the high-voltage supply conductors are routed directly between the interconnected switchgear. Thus, no special seal against gas / air leakage to or from the atmosphere needs to be made. Thus, each switchgear can be prepared for such joining by having corresponding switchgear walls provided with a removable cover plate. When joining two or fl your steelworks, these cover plates are removed and the respective busbars in each steelworks are screwed together. This entails a significant advantage over known steelworks. in particular relative to those with SF6 gas-insulated closed tanks, where one cannot directly access the rail system. At these known steelworks, one must provide the switchgear units with bushings and expensive so-called Elbow cable connections in order to be able to connect and connect them.

Incidentally, it is appropriate that the switchboard's air-insulating internal space is freely connected to the surrounding external atmosphere. This is advantageously done via filters.

Further advantages and embodiments of the steelworks according to the invention will appear from the following description, which is given in connection with the accompanying drawings, in which fi g. 1 shows a section from the side through the steelworks according to the invention, fi g. 2 shows the steelworks according to fi g. 1 in perspective but without operating mechanism and rotated 180 degrees and fi g. 3 shows a section lll - lll through the steelworks according to fi g. 2.

The following description of the steelworks according to the present invention illustrates its basic structure for a three-phase application for a high-voltage network.

In the sectional view according to fi g. 1 thus shows an exemplary three-phase embodiment of the steelworks according to the invention seen from the side. The switchgear is housed in an enclosure 1 forming an internal space consisting of a sheet metal tank. Each phase R, S, T comprises a circuit breaker 2, preferably of the vacuum type, above a disconnector 7. A first control shaft 3 is arranged to operate via a link 4 with insulating part 17 the contact connection 5 of the circuit breaker 2 to and from the incoming voltage supply rail 13, respectively. A second operating shaft 9 is arranged for operating the disconnector 7 between an earth contact 18 and a switch contact 19. The operating shafts 3 and 9 are controlled by means of an operating mechanism (not shown, per se known). It is independently controlled by tar control.

The circuit breaker and disconnector unit 2, 7 is mounted via a support insulator 15 on a bottom beam 10. The support insulator 15 is made as a penetration of glass fi reinforced 10 20 25 30 534 914 6 thermoplastic for a line 8 emanating from the switchgear at the bottom. This line 8 continues to a bushing 11 extending from the switchgear enclosure 1, to the outside of which connection can be made for electricity distribution to other appliances.

The essential feature of the switchgear according to the invention is best seen in fi g. 2, where the switchgear is shown in perspective and where the same reference numerals are used as in fi g. 1 for corresponding components. The feature is to be found in the combination of two different single-phase insulations, partly the one consisting of air of atmospheric pressure, which generally prevails both inside the switchgear enclosure 1 and outside it, partly the one with which the outgoing line 8 is provided. Thus, the line 8 is designed as a metal conductor insulated with shrink plastic 14 or other insulating material, as illustrated by the detail magnification shown in fi g. 1. This means that despite the fact that only air of atmospheric pressure is used as single-phase insulation in other respects, the switchgear can be made compact.

Simple flat insulating screens 6, arranged between each of the phases R, S, T within the area of the circuit breaker and disconnector unit 2, 7, constitute single-phase insulation in the upper space. These screens 6 ensure that no flashes occur between the different phase voltages. A disconnection of the disconnector 7 therefore only means that a possible arc occurs during the contact knife movement of the disconnector 7 towards the ground contact 18, which is arranged on the bottom beam 10 and to which the disconnector 7 is connected at its disconnection position.

Since it is often required that the lines emanating from the switchgear via the bushing 11 must be directed in the same direction as the control shafts 3, 9, problems often arise with the geometry for the laying of the lines 8 and the resulting insulation. Due to the insulation technology that characterizes the present invention, this problem has been completely eliminated.

In addition, by providing the bushings 11 with a cap 16 each, a good transition between conductor and bushing has been obtained. This cap is preferably made of silicone rubber. On the outside of the bushing 11, i.e. on the part which lies inside the tank, silicone rubber with a special shape 20 can be arranged which increases the creep distance and is hydrophobic. This prevents creep overruns and at the same time allows a more compact design. Thus a good insulating ability is obtained even if the air insulation used would be encumbered with contaminants in the form of moisture, salts, dust particles and the like. This also means that the space inside the enclosure 1 can be in free communication with the atmosphere prevailing outside the switchgear. Preferably, an alternating opening is accommodated in the wall of the enclosure 1 for air exchange due to changes in air pressure in the atmosphere.

Since the switchgear's internal space as phase insulation uses air of atmospheric pressure, an expansion of the switchgear can be achieved with small means. Thus, two or fl your switchgear are combined to lie next to each other. The only measure that needs to be taken is to open up openings for the travel of the busbars 13 between the various interconnected switchgear. No action against gas or air leakage is required.

The above description has focused on a special embodiment of the switchgear according to the invention. Of course, various modifications and further developments can be made without departing from the concept of invention, as expressed in the appended claims.

Claims (18)

10 20 25 30 534 914 PATENT REQUIREMENTS High-voltage switchgear comprising circuit breakers (2) and disconnectors (7) arranged in series one above the other in a single-phase insulated design and with control shafts (3, 9) for the circuit-breaker (2) and the disconnector (7), respectively, two different types of single-phase insulation is used for the circuit breaker and disconnector unit (2, 7) and for phase lines (8) emanating from the switchgear at the bottom, characterized in that the single-phase insulation is air insulation and screens (6) between the phases of the circuit breaker and disconnector unit (2, 7). Switchgear according to Claim 1, characterized in that the single-phase insulation for the phase line (8) emanating from the switchgear on the lower side is made of artificial material (14) directly applied to the surface of the phase line (8). Switchgear according to Claim 2, characterized in that the single-phase insulation of the phase line (8) extending on the lower side consists of shrink plastic (14) applied to the phase line (8). Switchgear according to Claim 1, characterized in that the circuit breaker (2) is of the vacuum switch type. Switchgear according to one of the preceding claims, characterized in that the circuit breaker and separator unit (2, 7) is housed in a space where air of atmospheric pressure and the screens (6) form the single-phase insulation, which space is separated from the part of the switchgear with phase-leading phase cable (8). Switchgear according to Claim 5, characterized in that the separation of the space for the circuit breaker and disconnector unit (2, 7) from the part of the switchgear with a phase line (8) extending downwards consists of an electrically conductive bottom beam (10) connected to earth. ). Switchgear according to claim 6, characterized in that the conductive bottom beam (10) forms part of the compartment or cabinet construction (1) in which the switchgear is housed. 20 25 30 534 914 Switchgear according to Claim 6 or 7, characterized in that the bottom beam (10) carries a phase bushing (15) of thermoplastic for discharging the outgoing phase-insulated phase line (8), which is connected on the upper side of the phase bushing (15) to the circuit breaker. and the underside of the separator unit (2, 7). Switchgear according to Claim 7, characterized in that the compartment or cabinet construction (1) has an outgoing bushing (1 1) for discharging the phase line (8) emanating from the switchgear on the lower side. Switchgear according to claim 9, characterized in that the bushing (11) is provided with a cap (16), preferably of silicone rubber. 1 1. of the bushing (11) located inside the compartment or cabinet construction (1), is Switchgear according to Claim 9 or 10, characterized in that on the part of it a part of silicone rubber with a special shape (20) is arranged for extending the creep distance and which is hydrophobic. Switchgear according to one of the preceding claims, characterized in that it consists of a three-phase switchgear with a separate circuit breaker (2), disconnector (7) and output phase line (8) arranged for each phase (R, S, T), the phases in the space of the circuit breaker and disconnector units (2, 7) are separated from each other by an electrically insulating wall (6). Switchgear according to claim 12, characterized in that the circuit breakers (2) in the three-phase system are arranged in line with each other as well as the respective associated disconnectors (7) for operation with a control shaft (3) for the circuit breakers (2) and a control shaft ( 9) for the disconnectors (7), the control shafts (3, 9) being mutually parallel. Switchgear according to Claim 13, characterized in that the operation of the control shafts (3, 9) is hand-independent. 534 914 10 Switchgear according to Claim 13 or 14, characterized in that the control shaft (9) of the disconnectors (7) comprises a torsion bar. Switchgear according to Claim 15, characterized in that the switching on (5) of the disconnectors (7) takes place by means of the spring force of the torsion spring (9). Switchgear according to one of Claims 12 to 16, characterized in that it is expandable by interconnecting luft your air-insulated three-phase switchgear wall to wall with common high-voltage supply conductors (13), which for each phase (R, S, T) are passed directly between the interconnected three-phase switchgear through removable openings in their walls. Switchgear according to one of the preceding claims, characterized in that the air-insulating inner space of the switchgear is freely connected to the switchgear surrounding the outer atmosphere via filters.