NL7810737A - MAIN DISTRIBUTION SUB-DISTRIBUTION SUB-DISTRIBUTION STATION FOR ELECTRIC ENERGY DISTRIBUTION. - Google Patents

Description

...... / Ν.Ο. 26,085 HAZEMEUER BV, in Hengelo.

Main distribution or sub-distribution station τοογ electrisohe energièilatri.T3ta, tie.

The invention relates to a main distribution station for electrical energy distribution with a high-voltage part, a medium-voltage part and at least one high-voltage transformer connected between them. The equipment also relates to a sub-distribution station which only supplies a medium voltage part ie to which medium voltage is supplied via a cable.

Main distribution station of the type mentioned in the preamble are generally designed as open-air stations at a large energy concentration, whereby due to the existing double line of the high-voltage distribution network, usually four incoming high-voltage lines are connected to a double busbar system via isolating switches and power switches. . This double rail system connects to two or three transformers, which in turn supply two or more medium voltage batteries. The medium voltage installation is usually also designed as a double rail.

Because of the high voltage, because of the high voltage, iaeen tends to build the high voltage part of such a main distribution station for a much larger energy concentration on t1 than is initially desirable. A corresponding voltage substation is unweimed because of the distribution. This also creates an unfavorable HS / MS cost ratio. With an increase in energy consumption, more is gradually invested in the MS network than in the HS part. However, this means that in the early years a large part of the installed HS-78 1 0 7 37 * * 2 installation will be used uneconomically and will only be used more gradually with the expansion of the MS network.

This initial over-investment would be avoided if appropriate other solutions existed.

The increase in energy consumption due to the population increase and urban expansions is still such that, partly due to the still relatively widely spaced main distribution stations, an MS transport cable quickly reaches its load limit, after which a parallel cable must be laid.

Because one will finally inject the energy via HS, this means investing in means that are only used for a short time. This is an extension option, which is accepted in combination with the then relatively lower HS investment.

Due to the ever-increasing amazement as a result of the increasing energy consumption, a need is growing for more simple main distribution stations and sub-distribution stations, respectively, which can inject into a medium voltage network via the HS energy in several places than was previously possible. To illustrate: injecting energy 20 half way through a 10 KY cable instead of at the end means that the maximum energy transport of the cable is generally doubled.

However, energy injection at considerably more places than is currently customary is becoming less and less possible with the existing main distribution stations because of their large dimensions of sometimes half a hectare and more. This is an even greater disadvantage for cities, because the need for more main distribution stations is growing here in particular.

The aforementioned large dimensions of the main distribution stations are necessary, inter alia, due to the economically most suitable air insulation at high voltages, generally 110 KY and higher, and the relatively large components thereby, such as power switches, coupling switches and isolating switches of the HS part. The large surface area of the 35 main distribution stations is also facilitated by the usual double-line and double-rail system.

The current HS distribution network is practically everywhere as a double-feeder 3, * because of its former function as a coupling network.

This means that in main distribution stations usually four HS lines are connected to a double rail system. As mentioned above, two or three transformers are connected to this 5, which in turn supply two or more MS batteries, these MS installations usually also being equipped with double rails. In general, a limit to switch to double rail is approximately 10 MVA 10 and this limit is usually reached quickly in the cities, so that people also have to rely on a double rail system.

There are many reasons for the use of double rail systems, such as the most favorable possible load distribution of the stations; the possibility of different voltage levels during operation; expansion and maintenance without business interruption; a limitation of the short-circuit power, a facilitation of the ground fault location. If, however, other solutions are available for the aforementioned issues, designers are inclined to abandon the double rail system.

The present invention now provides a main distribution station and a sub-distribution station of the type mentioned in the preamble, which take into account the complex of the above-mentioned drawbacks of the existing means and the requirements regarding the easy and gradual expansion, both with regard to the HS Installation as the MS installation.

. The main distribution station according to the invention is characterized in that both the HS part and the MS part consist of at least one multi-phase power supply unit, which is mounted such that it can be assembled into a closed power supply ring with corresponding further power supply sectors, the The HS supply ring is axially above the MS-35 supply ring, while the HS transformer is arranged next to these rings, each HS supply sector consisting of one HS circuit breaker, two connected by the power switch connecting rail sections extending over a portion of said feed ring; HS isolating switches, with which the two rail sections' 5 can be connected to the HS supply line or to the HS winding of the transformer; means for connecting the ends of the rail sections not connected to the HS power switch to corresponding ends of rail sections of further adjacent power sectors in the power ring, while the MS power sector consists of a rail section curved according to an eccentric peripheral part; an MS power circuit breaker, which can connect the rail sections to the MS winding of the transformer or to a power cable; MS outgoing 15 power switches, each of which can connect the rail section with an outgoing MS cable; coupling means for connecting the existing rail section to further rail sections, which. Spatially limit the existing rail section in the MS supply ring to be formed. 20

In a preferred embodiment of a main distribution station according to the present invention, one end of the MS rail section is connected to the MS power circuit breaker, while the MS outgoing power switches are evenly distributed on the rail sections and each 25 MS power switch is outside the MS power ring arranged within an associated echoes sector adjacent to the rail section.

In the one or more further MS rail sections, the free end of the existing rail section not connected to the MS power circuit breaker is connected via a coupling power switch or isolating switch to the spatially adjacent end of the further MS rail section, the other end of which the associated MS power vacuum circuit breaker is connected and / or the side of the 78 1 0 7 3 7 5 connected to the HS transformer and the cable respectively. ·: · Ί * r.

the iB power supply switch of the existing rail section connected to the corresponding side of an MS power supply switch of the rail section which is spatially adjacent in this end of the existing rail section, the other end of which is connected via a vacuum coupling switch to a further, spatially adjacent MS- rail section can be connected.

A closed MS supply ring according to the invention consists of several, for instance four, track sections bent according to a part of a circle, the connections between two ends of adjacent track sections in the ring opposite to each other alternately consisting of a torque power switch or disconnector, respectively, consisting of two series-connected MS power supply switches, the common connection point of which is connected to the high-voltage transformer and the cable, respectively. The medium voltage supply ring is further provided with a plurality of MS earthing switches for the grounding of each rail section and of each outgoing MS cable.

The entire main yer substation according to the invention '20, with the exception of the transformers, but with the same capacity as the current existing open air main substations, can be accommodated in a two-storey tower or column with a diameter of approximately 6 meters and. a height of about 10 meters. The 25 MS installation is then mounted in the ground floor on the ground floor or completely or partially buried in connection with the incoming and outgoing cables or limited construction height, while the high-voltage section is located on the second floor above the medium-voltage section. A single pile or a sheet metal frame can serve as a foundation, which extends into the MS part of the house and carries the floor of the second floor, while on the ground floor the medium voltage ring is suspended from this frame. The high voltage section can be at the same level as the high voltage supply lines for the stations 7810737 6 of the rural section of the high voltage network. In cities where high-voltage cables must be used, large basements are avoided due to the radius of curvature of the high-voltage cable. The required building plot of the order of 20 x 10 meters, including two transformers, is minimal compared to the above-mentioned conventional overhead distribution stations. This is particularly important because high-voltage distribution stations now have to be installed in densely built-up inner cities. The building can be built entirely in a factory from prefabricated elements and installation parts. However, the installation parts, such as busbar sections and switches, can also be easily replenished at any time, which allows a gradual growth of both the high voltage part and the medium voltage part. The construction materials are reduced to a minimum, while such a main distribution station in the form of a small column or column in the landscape and also within the cities will be experienced as hardly visually disturbing. At an equal power of 40 MW, the cost of a main distribution station according to the present invention will be considerably lower than an above-mentioned main distribution station insulated by atmospheric air.

The input means for the lines and connections to the high-voltage transformers can be designed as arms integrated with the building, which carry the insulators, which also applies to the input means to the high-voltage lines. The station also functions as a mast.

Instead of the usual double rail system 30, a ring installation is now used, which, like this double rail system, offers maximum operational possibilities. At the most, the rail will only need to transport 75 $ of the maximum transformer power, that is, with open ring. In the event of a fault in any 35 component, the energy supply can always continue to take place through the remaining part of the ring. Circuit breakers that are most subject to inspection can be easily disassembled, because of their arrangement in a circle * * or ring sector outside the supply ring, without "blocking a line or transformer". Installed in an outwardly widening circle - or ring sector, the length of the rail is no longer determined by the widest component of the field, such as a vacuum switch, for example, which makes it possible to keep the rail length as small as possible, but it is not immediately necessary to extend the main distribution station to closed ring systems. As with conventional stations below about 10 MVA with a single rail will suffice, the station of the present invention may initially only install part of each ring, it should be noted that extension of the ring is possible while the station is operating.

At the existing main distribution stations with insulation by atmospheric air, although the increase in energy consumption could gradually increase the high voltage part 20, the expected maximum extension means that one must have access to it from the outset. a much larger ground area.

The arrangement of the installation parts at the main distribution station according to the present invention is further such that, in terms of heat development, the most heavily loaded parts, such as rails and power switches, can very easily be forced with a single cooling unit, resulting in an overload of 30%. $ allows. Due to the ring shape with a small diameter of about 120 cm, the rails are further extremely short, so that only a small heat development will occur. The MS installation will contain a minimum of combustible material if vacuum power switches are used herein and if the components, which due to their explosive nature, can ruin the installation, such as gas-producing switches and terminations for wet cables outside the terminals. «·

J

8 installation and no oil switches are used. The rail sections and the vacuum switches mounted for the MS part will preferably be cast in insulating material without an air gap. The outgoing fields of the medium voltage section can be mounted on the medium voltage rail sections without or without an air gap.

All operating means for the vacuum load switches for grounding the rail sections and cables will preferably be coupled to each associated vacuum power switch such that before the earth load switch can be turned off, the associated vacuum power switch must be fully turned off and vice versa. This can be done simply by having the switches steered by the same operating mechanism. All further necessary installation parts, such as current transformers, capacitive voltage dividers for voltage indication, the connections to the cable terminations can be mounted directly or directly next to the rail sections and the whole can be surrounded by a sheet metal box in the form of a console. in which blind diagrams, position detectors, ammeters and voltmeters are included. A particularly compact distribution station is thus obtained.

Outside of the house, movable transformers can be arranged on rails in a simple manner, which is particularly useful for exchanging and for load adjustment.

The problems mentioned in the preamble, which the existing main distribution stations entail, are solved by the main distribution station according to the invention. With a compact main distribution station according to the present invention, energy can easily be injected into an existing MS network at many more points than hitherto. The main distribution station according to the invention provides an adequate replacement for the double rail system in closed supply circuits, while both the medium voltage part and the HS part allow a gradual extension, whereby 78 1 0 7 3 7 f-r ·:.

9 initially large investments become superfluous.

The invention also provides a medium voltage sub-distribution station which is not fed by a high-voltage part with transformer, but from a medium-voltage cable which is connected elsewhere to a main distribution station or another sub-distribution station. These sub-distribution stations contain only the mid-voltage section of the main distribution stations according to the present invention. Such sub-distribution stations permit MS energy injection where there is no need yet for an injection from a high voltage line. If the energy consumption increases above a certain limit, a similar sub-distribution station can very easily be extended to a main distribution substation.

For this purpose, only one top floor needs to be installed and transformers installed. Because of the small ground area to be reserved, this can easily be taken into account from the start,

The invention will now be further elucidated with reference to the drawings, on which embodiments f are shown. . 20

Dig. 1 shows a schematic vertical section, partly in view, of a main distribution station according to the present invention; Fig. 2 schematically shows a cross-section, partly in elevation, through the high-voltage part of the main power supply; substation according to the present invention; Fig. 3 shows a top view of a partially installed high-voltage section, a so-called installation of a main distribution station according to the present invention; Fig. 4 shows a completely closed supply ring according to Fig. 3, of a high-voltage part, a so-called H-ins tallation; FIG. 5 is a top plan view of the medium voltage section of a main distribution station according to the present invention; 78 1 07 37 y 10 Figures 6 to 9 show expansion possibilities of the medium voltage part of a main distribution station according to the invention; Fig. 10 shows a partial vertical section through the medium voltage section along the line X-X in Fig. 5; Fig. 11 shows partly in section a sub-distribution station according to the present invention,

In the figures to be discussed below, like reference numerals give equal parts of the main distribution station and the sub-distribution station according to the present invention.

In fig. 1, which shows a cross-section and a partial view of the main distribution station according to the invention, a column or column-shaped house 1 is divided into two floors by a floor 2, which is carried by a pole or frame 3, which pole or frame itself can form the foundation of the main distribution station, but can also be placed on a separate foundation. The house is covered by a roof 4. The house 1 is further provided with doors, windows and stairs or 20 ladders (not shown) along the side walls. The width of this house, with a power of 40 MVA is about 6 m, with a height of about 10 m.

On the top floor, the high voltage part is placed on the floor 2, which is generally indicated by 5, while on the ground floor the medium voltage part 6 is mounted. This medium voltage part 6 is shown here as a closed ring, which is only the case in the final situation of the station, which ring is suspended from the frame 3 or rests on the bottom of the housing 1. 30

Outside the house, two transformers 7 and 8 are schematically shown.

Fig. 2 shows a section through the high-voltage section 5 of the housing and a plan view of the transformers 7 and 8. On the side wall of the housing the carrying arms 9 and 35 10 are arranged for the input of the high-voltage lines 78 1 0 7 3 7 - *. . .. f - 11 '"'. F 11 and 12, which are made ala overhead lines. These support arms 9 and 10 can be integrated with the wall of the housing. The drive as high voltage 11 and 12 are attached to insulators 13 and H, from which a connection runs to the suspension insulators 15 and 16 attached to the arms 9 and 10. These are feed-through insulators, via which the high voltage is supplied through input conductors 17 and 18 to the high-voltage part 5.

In this complete main distribution station, the high-voltage section 5 consists of straight, three-phase rail sections 19 to 22 10 which can be connected to each other by high-voltage power switches 23 to 26, which are raised in the vertices of a square * Each of the rail sections 19- 22 consists of two mutually extended rail sections, which are also connected to each other, so that a total of eight half rail sections are obtained. The connections between the three-phase input conductor 17 and 18 and three-phase rail sections 19 and / or 21, respectively, and between the rail parts of each section are established by the connection points between the input conductors of the rail sections and the rail parts showing only three schematically shown three-way high-voltage isolating switches 27 and 29. Similar three-way high voltage disconnect switches 28 and 30 can connect the rail sections 20 and 22 or their rail sections to the primary high voltage windings of the transformers 7, 25 and 8 placed outside the sleeve 1. SE6-filled switches can be used as high-voltage power switches *

The connection between the trip-way disconnectors 28 and 30 and the primary windings of the high-voltage transformers 7 and 8 is effected in the station shown in Fig. 1 by encapsulated conductors, see reference numerals 31 and 32. However, this can also be done using arms corresponding to arms 9 and 10, through which the high voltage lines 11 and 12 are connected. These arms, not shown in the figures, can also be integrated with the housing 1 and here extend in 7810737 12 a direction perpendicular to the direction of the shown arms 9 and 10 via which the overhead lines of the HV network are connected. .

The high voltage power switches 23 to 26 are only schematically shown in Figs. 1 and 2 and consist of an operating mechanism housed in the vertical housings 33 and 34 in Fig. 1. At the bottom, these housings are 33 and 34 show the switching elements for interrupting the connections between the four rail sections. 10

The power supply in the high-voltage section extends from the high-voltage lines 11 and 12 through the input conductors 17 and 18, the associated three-way switches 27 and 29 to the two rail sections 19 and 21. The ends of these rail sections, ie the outer ends of the rail sections of each section terminate in high voltage power switches 23 and 24 and 25 and 26, respectively. The other sides of these power switches are connected to the adjacent parts of the rail sections 20 and 22. These rail sections can be connected by means of three-way disconnect switches 28 and 3o are connected to the encapsulated conductors 31 and 32 which lead to the primary windings of the high voltage transformers 7 and 8, respectively.

Figures 3 and 4 show expansion possibilities of the high voltage section in a main distribution station according to the present invention.

Dig. 3 shows the embodiment in which a transformer will suffice for the time being. This is a so-called T-installation. In both arms 9 and 10 the high-voltage lines 11 and 12 terminate again, which are suspended from the insulators 13 and 14, respectively. With the hanging feed-through insulators (not shown) and the input conductors (also not shown) the high voltage ends up at the schematically indicated three-way isolating switches 27 and 35 29, which, in this incomplete embodiment, have a connection 78 1 0 7 3 7 '13. . '* be able to' establish 'with the rail parts of the half rail sections 19 and 21. Both the input conductors 1? and 18 if the rail sections 19, 20 and 21 are housed in gas-filled tubes, but may also be insulated in other ways.

The existing parts of the rail sections 19 and 21 end 5

again in power switches 24 and 25. The complete rail section 20 extends between these power switches, in the middle of which it extends 28; again a three-way isolating switch, which can connect the rail sections to the supply conductors to transformer 7. This is done here with the aid of an arm 35 »integrated on the loom, which is of the same design as the arms 9 and 10. On the underside of this arm 35 there are lead-through insulators, from which conductors are fed to the primary winding of the high-voltage transformer . 15; T

Dig. 4, as already mentioned, shows a high-voltage section with a complete supply ring, a so-called H-installation. Here too the rail function. 22, as well as the rail section 20 in FIG. 3 via an arm 36 and the conductors therein and feed-through capacitors connected to the 20 20 primary of the second high voltage transformer, 1 not shown here either. The other parts are indicated with the same reference numerals as in the preceding figures.

A ring installation naturally offers the maximum 25 options in terms of business operations. In the event of a fault in any component, the energy supply can always continue to take place through the rest of the ring. The circuit breaker most subject to inspection due to the disconnection of 30 short-circuit currents can be disassembled without blocking a line or transformer. The installation also takes into account the fact that afterwards switches of a better type can be installed.

Pig. 5 shows a top view of a medium voltage part according to the invention. In the middle again is the column or the frame 3, on which the entire medium voltage 7810737 Η part can be suspended. The numerals 37, 38, 39 and 40 indicate the encapsulated MS-rail sections. These are completely encapsulated in insulating material, see fig. 10, which gives a vertical section along the line XX in fig. 5 · On the right in fig. 10, the three phases 5 R, S and T of the medium voltage rails are visible, which in insulating material 50 are poured in. Connected clockwise from the lower left end to the upper right end, a bus power supply switch 41, then five power output switches 42 to 46, which lead to the outgoing cables, and a coupling switch 47, respectively. the power supply switch 41 is supplied with current from the secondary low-voltage winding of one of the transformers to the rail section 37, which current can be supplied to the outgoing cables by each outgoing switch 42 to 46 of the various medium voltage fields. The coupling switch 47 offers the possibility of connecting the rail section 37 and 40 together. The further rail sections 38, 39 and 40 are designed in the same way as the rail section 37, with the difference that in the rail sections 38 and 40 the flow direction is opposite to the direction in sections 37 and 39, if at least the ring is uniform is taxed. Sections 37 and 38 are connected to one transformer by their power switch 41 and rail sections 39 and 40 via their power switch 41 to the other transformer. In each end of the various switches remote from the rail sections there is a tube mechanism 59, shown only schematically, by means of which each switch can be operated. The earthing switch can also be operated with the same tube mechanism, by means of which either one of the rail sections or the associated outgoing cable is laid to earth. The different switches preferably consist of vacuum switches. 35

In Figs. 6, 7, 8 and 9, the expansion possibilities are possible. The MS part of a main distribution station and a sub-distribution station according to the invention are indicated respectively today. Initially, a rail section can be started, according to the embodiment in Fig. 6, in which the same reference numerals indicate the same parts as in Fig. 5. In such a situation, the power supply takes place via a power supply cable. To have the ability to ground the power cable without simultaneously grounding the rail, one of the switches 42 through 46 is used as the power switch. The power switch 41 can then be omitted in the first instance. Fig. 6 also shows the earth load switches, with which the rail section 37 and the various cables can be connected to earth behind the outgoing vacuum switches 42 to 46. These earthing switches consist of vacuum load switches and are indicated with reference numeral 48 in the figures. In fig. 7 a second rail section 40 is mounted, for which in this case a second power supply cable has become necessary, to which one of the right flake switches 42 to 46 is again connected. When one of the power supplies 20 is lost, the rail section concerned can be fed by the undisturbed rail section by closing the coupling switch 47.

Further possibilities for expansion are indicated in Figs. 8 and 9. For the sake of clarity, most reference numerals have been omitted from the various vacuum switches in Figs. 8 and 25.

In Fig. 8 a further extension is indicated with a third rail section 39. In this situation, a transformer provides the power supply and for this purpose both right-hand vacuum power switches 41 are connected together to that transformation. In order to guarantee an undisturbed power supply, for example in the event of the transformer power supply being cut off, the existing cable power supplies of the rail sections 37 and 40 can be maintained. Optionally, an outgoing field can also be used for the rail section 39 to provide that rail section with a cable supply.

78 1 07 37 y * 16

Fig. 9, finally, shows the fully assembled MS section of a main distribution station and a sub-distribution station according to the invention, respectively. A second transformer has been added, so that the entire installation can be powered by transformers. The power fields used for the cable power supplies can then serve as outgoing fields.

These drawings clearly show the gradual expansion possibility of the MS part in a main distribution station according to the invention, which however also applies for a sub-distribution station according to the invention. The medium voltage power supply ring consisting of the rail sections 37 to 40 can be gradually built up as the energy requirement in a service area increases. Initially, a track section will suffice and the coupling switch 47 and the power switch 41 will be omitted. If the energy requirement increases, a second supply cable is connected to the distribution station and a further rail section is mounted, in Fig. 7 the rail section 40. The extension is of course not limited to the form shown in Fig. 7. Also, instead of rail section 40, the second section can be provided with rail section 38, see Fig. 9. In that case, both sections 37 and 38 can be fed either from a transformer or via cables. Owner.

8 shows the next step in the extension of the medium voltage section after the step shown in FIG. 7, while FIG. 9 shows the final fully completed medium voltage installation.

For the medium voltage section, the heat development is minimal due to the very small rail length. The 30 'rail sections 37 to 40 can be completely cast in the factory together with their connection and coupling means. The ring arrangement makes forced cooling very easy to perform. The coupling switches 47 between two adjacent rail sections in the supply ring serve just like the other 35 vacuum switches for the rail protection, but 78 1 0 7 37 r: .......- τηρ V Η also serve as the transformer protection switch.

These coupling switches, like the rails, do not have to carry more than 75 $ of the maximum transformer load. It goes without saying that all vacuum circuit breakers are also three-phase here. 5

Fig. 10 shows in more detail the arrangement of the vacuum power switches and load switches for grounding the cables and busbar sections of the medium voltage section. The figure shows a cross-section over an outgoing field, namely with switch 44 in fig. 5 * This vacuum switch 44 is connected on the right-hand side to a phase of the rail section 37 · rail 49 of this rail section is completely encapsulated in insulating material 50 which, as also appears from Fig. 5, is provided with a hollow part 51 protruding to the left, into which a bush-shaped end of a housing 52 of insulating material fits. This casing 52 contains the outgoing vacuum power switch 44. From this power switch, a current conductor 53 runs to the right through the hollow part 51 to an opening in the rail 49 * Sealed between the inner wall of the hollow part 51 and the outer wall of the neck-shaped right end of the housing 52 material.

The housing 52 is closed on the left by a second insulating material housing 54, which contains the actuating means for the traditional switch 44 and the grounding switch 48. The movable current conductor 64 of the switch 44 can move one of the switch contacts to turn the switch 44 on and off.

The current conductor 64 shows the connection means 55 for the outgoing cable 56 of a field. This cable is also connected by means of connecting means 57 to the left movable current conductor 65 of the earthing switch 48. The right-hand current conductor of this earthing switch is connected to the earthing rail 58. Also, the left movable current conductor 65 of switch 48 is connected to the operating means in the housing 54. The operating means 78 are coupled to a tubular mechanism 59, which can be turned with a selector button 60. By moving the selector knob in axial direction, either vacuum switch 44 or vacuum switch 48 can be operated, so that either cable 56 is connected to rail 49 or cable 56 is grounded. Operating means for alternately operating the two vacuum switches can further be realized in a very simple manner with the aid of this tubular mechanism 59 and also provides in a simple manner the necessary mechanical interlock between the power switch and the earthing switch.

In FIG. 10, the vacuum supply power switches and the vacuum load circuit breakers for the rails of phases S and I of the same field are shown schematically.

Their design, of course, corresponds to the embodiments shown in cross-section in Fig. 15.

Fig. 10 further shows the suspension means for the rails and vacuum switches as well as the operating members for the vacuum switches. The whole is built into a lectern 61, in an upright part 62 of which, for example, ammeters 20 and voltmeters 63 as well as signaling means can be built in. For each of the rail sections 37 to 40, a curved desk running along with the rail section can be used.

As can be seen from Fig. 10, but also from Fig. 5, the rails can be kept very short, because the vacuum switches are connected to these rails at their narrow end. A shortening of the rail length is therefore only possible when a circular feed rail with fields placed outside it is used. The wider 30 parts of the vacuum switches are further away from the rails.

Disassembling a switch can be done very easily by pulling the switch away from the rails.

Fig. 11 shows a cross-section of a sub-distribution station according to the invention. This sub-distribution station 35 comprises only the ground floor with the contents of an area. 19, Ρ for described main distribution station. An important advantage of a subdistribution station according to the present invention is that afterwards it can be very easily up to a ΐ; main distribution station can be supplemented, for this purpose only the frame 3 which is only schematically shown in fig. 11 needs to be extended upwards. A floor must be placed on this frame and the high-voltage section is then mounted on it. Naturally, the house is also extended upwards. Power supply for the high-voltage part can then be via an air line or also via a. high voltage cable. In the latter case, extra space for the transformers is not necessary at all, as only height is built. p

The sub-distribution station again comprises a house 1, the foundation of which is shown here, and the spaces in which 15. the cable terminations 62 for the different fields. The medium voltage section 6 is further designed in the same manner as shown in FIGS. 5 to 10.

The sub-distribution station according to Fig. 11 can also be partially or completely built into the ground. This can be useful, for example, if insufficient height is available or permissible for extension to a complete main substation built from the ground floor. -

The moment at which me® changes from a sub-distribution station to a main distribution station depends on the economic conditions determined by the growth. At the presently known main distribution stations, the investment in the medium voltage section will continue to be extended for longer, in which case the initial power of the HV part of the main distribution station is very high. Indian is going out 30

of a sub-distribution station according to the present invention, '. P

as shown in Fig. 11, since the invention also provides a modified HS section, one will be much more likely to hack this ox into a main distribution station. However, neither the main distribution station nor the sub-distribution station initially need to be at full capacity. 78 1 0 7 3 7

Claims (20)

1. Main distribution station with a high-voltage part (HS) and a medium-voltage part (MS7 and at least one high-voltage transformer connected therebetween, characterized in that both the HS part and the MS part consist of at least one multi-phase power supply sector, such that it can be assembled into a closed supply ring with corresponding further supply sectors, the HS supply ring being located axially above the 20 MS supply ring, while the high-voltage transformer is arranged next to these rings, each HS supply sector consisting of an HS power switch, two by the busbar sections to be connected to each other, which extend over a part of the said supply ring 25. HS isolating switches, with which the two rail sections can be connected with the HS supply line and with the HS winding of the transformer, means for connecting the end not connected to the HS power switch one of the rail sections on corresponding ends of rail sections of further adjacent power sectors in the power ring, while the MS power sector consists of a track section curved in a circular circumference; an MS power circuit breaker, which can connect the rail sections to the MS winding of the transformer with a power cable, respectively; MS-going 78 1 0 7 37 "* ',; i 21'." Circuit breakers, each of which can connect the rail section with an outgoing MS-cable; coupling means for connecting the existing failure section to further rail sections, which are to be formed MS mounting ring; spatially adjacent to the existing rail section * 5 2. Main distribution station according to claim 1, provided with a plurality of supply sectors, characterized in that the HS isolating switch is a three-way switch with which the HS supply line and the HS winding of the transformer can be connected to either or one of the opposite parts of a rail section which are located at one another, and with which these two parts can be connected to each other. Main distribution station according to claim 1 or 2, characterized in that one end of the MS rail section 15 is connected to the MS power circuit breaker and the MS outgoing power switches are evenly distributed on the MS rail section while each MS circuit is connected. circuit breaker outside the MS supply ring is arranged within a] adjacent to the MS rail section? associated ring sector. Main distribution station according to claim 1, 2 or 3, characterized by a plurality of MS ground load switches for grounding each MS rail section, respectively, of each outgoing MS cable * 25 5. Main distribution station according to claim 3, characterized in that; of one or more further MS rail sections, the free end of the present MS rail section not connected to the MS power supply switch is connected via a coupling power switch to the spatially adjacent x end of the further MS rail section, the other end of which with the associated MS power supply switch is connected and / or the side of the MS power supply switch of the present MS-35 rail section connected to the HS transformer or the cable is connected to the corresponding side of 78 1 07 37 22 an MS power supply switch of the this end of the MS rail section present in a spatially adjacent rail section, the other end of which can be connected to a further spatially adjacent MS rail section via a coupling power switch. 5 6. Main distribution station according to claim 5, characterized in that the further MS power supply switches and the coupling power switch are arranged within an external ring sector adjacent to the rail section. Main distribution station according to any one of the preceding claims, characterized in that all rail sections and power switches of the MS part are cast in insulating material. 8. Main distribution station according to one of the preceding claims, characterized in that all said MS switches are vacuum switches. Main distribution station according to one of the preceding claims, characterized in that a closed HS supply ring consists of four HS circuit breakers placed in the corners of a square, which are connected to each other by straight track sections and on the central parts of these rail sections the HS isolating switches are connected. 10. Main distribution station according to any one of the preceding claims, characterized in that a closed MS feed ring consists of a plurality of circular sections curved in a circle circumferential section, the connection between two ends in the ring opposite each other from in the ring adjacent x MS rail sections alternately consist of a torque power switch, respectively, of two series-connected MS power supply switch systems, the common connection point of which is connected to the HS transformer. 11. Main distribution station according to one of the preceding claims, characterized in that the high-voltage section and the medium-voltage section are located in a two-storey tower-shaped house, the high-voltage section in the upper floor and the medium voltage member is located in the lower floor * and both parts are supported by a central mill arranged axially relative to the feed rings in the housing, which carries the floor of the second floor and from which the MS feed ring is suspended. 12. Sub-distribution for medium voltage, known by at least one multiphase power supply sector which is mounted in such a way that it can be assembled with a corresponding further power supply sectors into a closed power supply ring, each sector consisting of a track section curved according to a circular peripheral section. ; a power supply switch, which can connect the rail section to the MS power cable; outgoing power switches, each of which can connect the rail section to an outgoing field; coupling means for connecting the existing rail section to further rail sections, which spatially adjoin the existing rail section in the supply ring to be formed. . 20 13. Sub-distribution station according to claim 12, characterized in that one end of the rail section is connected to the power circuit breaker and the outgoing power switches are evenly distributed on the rail section, each power switch being disposed outside the power ring , within an associated ring sector adjacent to the rail section. 14. Sub-distribution station according to claim 12 or 13, characterized by several earth load switches, for earthing of each rail section and of each outgoing cable. 15. Sub-distribution station according to conelusion 13, characterized in that of one or more further rail sections, the free end of the existing rail section, which is not connected to the power supply switch, is connected via a coupling power switch to the spatially adjacent end of the rail section. further rail section, the other end of which is connected to the associated power supply switch and / or the side of the power supply switch of the existing rail section connected to the MS power supply cable is connected to the corresponding side of the power supply switch of the, in this end of the rail section spatially adjacent rail section, the other end of which can be connected via a coupling power switch to a further, spatially adjacent subsection. . 10 Sub-distribution station according to claim 15, characterized in that the further supply power switches and the coupling power switches are arranged within an external ring sector adjacent to the rail section. Sub-distribution station according to any one of claims 12 to 16, characterized in that all rail sections and switches are cast in insulating material. Sub-distribution station according to one of Claims 12 to 17, characterized in that all said switches consist of vacuum switches. 20 19. Sub-distribution station according to one of Claims 12 to 18, characterized in that a closed supply circuit consists of a plurality of rail sections bent along a circular peripheral section, the connection between two ends opposite each other in the ring of adjacent rail sections alternately consist of a torque circuit breaker and of two series-connected supply circuit breakers, the common connection point of which is connected to the MS supply cable. Sub-distribution station according to one of Claims 30 to 19, characterized in that the feed ring is arranged in a circular housing, the ring being supported by a central, axial to the ring in the house prepared freem. 78 1 0 7 37