RU56078U1 - OPEN DISTRIBUTION DEVICE - Google Patents

Abstract

The utility model relates to the field of electric power industry, namely, to high voltage switchgears intended for receiving and distributing electric power. The essence of the utility model is that in the well-known switchgear containing a portal for attaching overhead lines and lines to T, there are two sections of busbars, high-voltage hardware complexes, each of which consists of at least one disconnector, circuit breaker, and current transformer, voltage transformers, surge arresters, as well as communications with overhead lines and with lines to T, high-frequency arresters and coupling capacitors, according to a utility model, high-voltage hardware complexes are fixed on foundation supports under busbar sections, fault sections busbars are connected to the disconnectors of the high-voltage hardware systems by hard bus runs, and the portals for fastening the links to the overhead lines and lines to T and the overhead lines and lines to T are installed between busbar sections, voltage transformers, surge arresters, high-frequency arresters and coupling capacitors are fixed to foundation supports also between sections of busbars at the level of high-voltage complexes, and the descents from busbars to disconnectors are made curved with a bending angle of 90 ° <α <180 °; portals for fastening overhead lines and lines to T are made with consoles, and busbars are mounted on supporting insulators installed on the consoles of the portals; at the same time, high-voltage hardware systems, high-frequency arresters, coupling capacitors, surge arresters and voltage transformers are installed on one frame; high-voltage hardware systems are fixed on the foundation supports under busbar sections with an offset of at least A _f-f from the portal to the overhead line or T. The application of the claimed utility model allows to reduce the area of outdoor switchgear, its material consumption and cost, and also requires a smaller amount of construction work.

Description

The utility model relates to the field of electric power industry, namely, to high voltage switchgears intended for receiving and distributing electric power.

Known open switchgears (switchgear) high voltage with a single-row arrangement of switches and other high-voltage devices (L.I.Dvoskin Schemes and designs of switchgears. M. Energy, 1974, S. 103, Fig. 2-21a), in which portals for attaching high-voltage lines (OHL) and lines to transformers (T) are installed on both sides of busbars, all devices are installed at about the same height, providing vehicles with access to them, etc., and therefore these outdoor switchgears occupy a large area

High voltage switchgears are also known, consisting of busbar sections, circuit breakers, current and voltage transformers and other devices, portals, busbars and other structures (Typical design “110 kV switchgear on standardized designs”, Energosetproekt, inv. No. 13189-tm; “ 330 kV outdoor switchgear on standardized structures ”, Energosetproekt, model No. 407-03-491.88).

The disadvantage of these outdoor switchgears is that they take up a lot of space, have a lot of metal and reinforced concrete structures and require a large amount of construction work at the site during the construction of the outdoor switchgear.

Closest to the claimed solution is an open switchgear ultra-high voltage (outdoor switchgear SVN) (AS USSR No. 725133, NO 2 V 5/00, 1977), consisting of switches, disconnectors, current transformers, forming high-voltage hardware systems, voltage transformers, high-frequency arresters, communication capacitors, arresters, portals, busbars, connections and additionally equipped with rigid conductors of disconnectors with spatial hinges on insulating structures under busbars ami. The busbars and busbar are fixed on the portals, the connections go to the side of the circuit breakers installed in phase, in one row, and the disconnectors are fixed on additional portals installed in two rows on each side of the circuit breakers.

The specified switchgear has much in common with the claimed switchgear. It has two systems (sections) of busbars, high-voltage devices are installed in one row across to the busbars, there are portals on which high-voltage lines (OHL) and lines to transformers (T) are fixed.

However, the indicated SVR switchgear (for 750 kV voltage was implemented at the Zaporizhzhya, Khmelnitsky and South Ukrainian NPPs) also has disadvantages: portals for attaching the overhead lines and lines to T are installed on the outside on both sides of the busbars, surge arresters (surge arresters) , high-frequency arresters, coupling capacitors are also installed on the outside of the busbar system (section) and connected to the overhead line.

All this leads to an increase in the area of outdoor switchgear, requires a large number of metal structures and foundations and a significant amount of construction work at the site.

Due to the fact that recently there are new designs of high-voltage devices and hardware systems, including gas-insulated and vacuum circuit breakers, new disconnectors, measuring current and voltage transformers with gas-insulated insulation that do not require during operation (for the entire service life of 30 years ) carrying out repair work (only routine inspections after 10-15 years of operation), the requirements for outdoor switchgear designs have also changed. In particular, the requirement to ensure the operation of cranes above the circuit breakers without disconnecting the connections became unnecessary, while the requirement for redundancy and reliability of power supply to consumers increased and, therefore, it became possible to disconnect one or more connections from the switchgear during equipment repair (if this is still necessary). or even a section of busbars. All this leads to the development of new designs of outdoor switchgear.

The objective of the claimed utility model is the creation of outdoor switchgear, which occupies a smaller area, requires less construction work and has less material consumption and cost.

The solution to this problem is achieved by the fact that in the well-known outdoor switchgear containing a portal for attaching overhead lines and lines to T, two sections of busbars, high-voltage hardware systems, each of which consists of at least

one disconnector, circuit breaker and current transformer, voltage transformers, surge arresters, as well as communications with overhead lines and lines to T, high-frequency arresters and coupling capacitors, according to a utility model, high-voltage hardware systems are fixed to the foundation supports under busbar sections, busbar sections connected to the disconnectors of the high-voltage hardware systems by runoffs from the rigid busbar, and the portals for securing the connections with the overhead line and with the lines to T and the overhead lines themselves and lines to T are installed between the collection sections busbars, voltage transformers, surge arresters, high-frequency arresters and coupling capacitors are fixed on the foundation supports also between busbar sections at the level of high-voltage complexes, and the descents from busbars to disconnectors can be made curved with a bending angle of 90 ° <α <180 °, portals for attaching overhead lines and lines to T - with consoles, and busbars mounted on supporting insulators installed on the consoles of the portals; at the same time, high-voltage hardware complexes, high-frequency arresters, coupling capacitors, surge arresters and voltage transformers can be installed on one frame, and high-voltage hardware complexes are mounted on foundation supports under busbar sections with a distance of at least A from the portal to the overhead line or T _ff

Figure 1 shows the design of the switchgear for a circuit with one partitioned bus system; figure 2 is a fragment of the circuit switchgear with one partitioned bus system; figure 3 - design of switchgear with one portal; figure 4 - outdoor switchgear with a biased high-voltage hardware complex.

The switchgear (Fig. 1) consists of portals 1, two sections of busbars 2 and 3, mounted on supporting insulators 4, switching devices - switches 5 and disconnectors 6, current measuring transformers 7, high-frequency traps 8 and coupling capacitors 9, overvoltage limiters 10 and voltage transformers 11.

The busbar sections 2 and 3 are connected to the disconnectors 6 by means of slopes bent at an angle of 90 ° <α <180 ° from rigid busbar 12 to ensure the distance A _{f f} .

A high-voltage line (OHL), mounted on portal 1, is connected to a coupling capacitor 9 and a high-frequency choke 8 through communication 13 with OHL, mounted on portal 1 between the busbar sections, and the line to T, also fixed on portal 1, but in another a cell connected to the disconnector 6 by a connection 14 with T, also fixed between sections of busbars.

Switches 5, current transformers 7 and disconnectors 6 are installed on a support 15 with a height of about 2.5 m. Devices connected to overhead lines, including high-frequency arresters 8, coupling capacitors 9, surge arresters 10 and voltage transformers 11 are installed between busbar sections on foundation supports (or support of figure 1) at the level of high-voltage hardware systems. To simplify the design of these devices can be fixed on one support 15 (figure 3). The supporting insulators 4, on which the busbars 2 and 3 are fixed, are mounted on metal supports 16. The portal 1 can be in the outdoor switchgear made with consoles 17 (Fig. 3), on which insulators 4 can be mounted for attaching the busbars. This simplifies the construction part. In the proposed switchgear, if you still need to fulfill the requirement to carry out repair work on the current transformer or circuit breaker without disconnecting the busbars, high-voltage hardware complexes can be fixed on the foundation supports under the busbar sections with the complexes offset from the portal 1 to the overhead line or T by a distance from the extreme phase of the busbar at least the distance "phase-phase" (figure 4). The distance between the phases of the busbars is made not less than the distance A _{f f} + b, where b is the phase width of the busbars.

The repair distance R between the vertical connections 13 with the overhead lines (connections 14 with T) and the horizontally arranged phases of the busbars is selected according to the operating conditions, but not less than the distance A _{f f} .

When the switchgear is energized and the switch 5 and disconnector 6 are turned on, the electric current from the transformer T through the connection 14 and the hardware complex enters the busbar section 3 (shown by a dashed line) and then through the sectional switch (Fig. 2) is supplied to the busbar section 2 from which the busbar 12 is fed to the upper current-carrying knives of the disconnector 6, the current transformer 7 and then through the switch 5, the lower current-carrying knives of the disconnector 6, the high-frequency trap 8 and communication 13

they feed the high-voltage line of overhead lines and further consumers. Or vice versa, the transformer T is fed from the overhead line in the reverse order

The application of the claimed utility model allows to reduce the area of outdoor switchgear, its material consumption and cost, and also requires a smaller amount of construction work.

Claims (5)

1. An open switchgear (ORU) containing a portal for attaching high-voltage lines (OHL) and lines to a transformer (T), two busbar sections, high-voltage hardware systems, each of which consists of at least one disconnector, circuit breaker and current transformer, voltage transformers, surge arresters, as well as communications with overhead lines and lines to T, high-frequency arresters and coupling capacitors, characterized in that the high-voltage hardware systems are mounted on foundation supports under sections with busbars, busbar sections are connected to the disconnectors of the high-voltage hardware systems by hard bus runs, and portals for fastening the links to the overhead lines and to the lines to T and the overhead lines and lines to T are installed between the busbar sections, and voltage transformers, surge arresters, high-frequency suppressors and coupling capacitors are fixed on the foundation supports also between busbar sections at the level of high-voltage hardware systems. 2. The open switchgear according to claim 1, characterized in that the descents from the busbars to the disconnectors are made curved with a bending angle of 90 ° <α <180 °. 3. The open switchgear according to claim 1, characterized in that the portals for attaching the overhead lines and lines to T are made with consoles, and the busbars are mounted on supporting insulators installed on the consoles of the portals. 4. The open distribution device according to claim 1, characterized in that the high-voltage hardware systems, high-frequency arresters, coupling capacitors, surge arresters and voltage transformers are mounted on the same frame. 5. The open switchgear according to claim 1, characterized in that the high-voltage hardware systems are fixed on the foundation supports under the busbar sections with an offset of at least A _{f f} from the busbar phase nearest to the portal to the overhead line or T.