NO793446L - MAIN STATION AND SUBSTATION FOR THE DISTRIBUTION OF ELECTRICITY - Google Patents

Description

Main station and substation for distribution of electricity.

The present invention relates to a main distribution station for the distribution of electricity comprising a high-voltage part (HV), a medium-voltage part (MV) and at least one high-voltage transformer connected between the parts. The invention further relates to a substation for the distribution of electricity comprising only a medium-voltage part to which the intermediate voltage is supplied by means of a cable.

Main stations of the above type are usually constructed as outdoor stations when there is a large concentration of energy, in which, taking into account the existing double lines of high voltage distribution networks, four incoming voltage lines are usually connected to a double busbar system by means of disconnectors and circuit breakers. This double busbar system has been connected by two or three transformers which in turn feed two or more medium voltage installations. The medium voltage installation is usually also carried out as a double rail system.

In view of the high voltage and with regard to the further supply of electricity, one is inclined to construct the high voltage part of such a main distribution station for a much greater energy concentration than is desirable to begin with. A corresponding intermediate voltage concentration is undesirable in relation to its distribution. Consequently, an unfavorable HV/MV cost ratio is also produced. With the increase in energy consumption, there will gradually be higher investment costs for the MV network than for the HV part. However, this means that within the first few years a large part of the installed HV construction will be used uneconomically and will only gradually become more economical when extended to the MV network. One would very much like to avoid these excessive investments in the beginning if there were other suitable solutions.

The increase in energy consumption due to the increase in population and urban expansion is still of such a degree that due to the relatively large distances between the main distribution stations, an MV transmission cable will soon reach its load limitations on which a parallel cable must be arranged. Where initially an HV application of energy is necessary, this means that the investment costs are made for devices that will only be used for a short time. This is an expansion option that will be accepted in combination with the relatively lower HV investment costs at that time.

Considering the ever-increasing interference with each other due to the increase in energy consumption, there is a growing need for more simple main distribution stations and respective substations, with the help of which HV energy can be imposed in medium voltage networks in more places than possible

•until now. As an illustration, the following can be noted: The energy application half-way on the 10 KV cable instead of on

its end means that the maximum energy transport capability of the cable will be doubled.

The pressing of energy by means of the soon-to-be-used main distribution stations at many more places than usual is now becoming more and more impossible considering the large dimensions of sometimes more than half a hectare or more. Too small

in places this is more harmful because the need for additional main distribution stations is increasing especially in such places.

The large dimensions of the main distribution stations are necessary, among other things, because air insulation is economically the most suitable for high voltages, usually of the order of 110 KV and more, and for consequently relatively large parts such as circuit breakers, circuit breakers and disconnect switches for the HV part. The large surface areas of the main distribution stations are also inspired by the double wire and double rail system such as is commonly used in the Netherlands. Existing HV distribution networks have been constructed as a double wiring network almost everywhere due, at least in part, to its design function as a switching network. This means that in main distribution stations four HV lines have usually been connected to a double busbar system. As already above

mentioned, two or three transformers are connected to this double rail system, which in turn feed two or more MV installations, where the MV installations are usually constructed as a double rail system. A limit at which one switches to the double rail system is usually around 10 MVA, which limit is usually soon reached in cities so that one becomes dependent on a double rail system even at this moment.

There are many good reasons for using double rail systems such as a load distribution of the stations that are. as favorable as possible, the possibility of several, voltage levels, the possibility of several voltage levels when in operation, expansion and maintenance without interruption of operation, a limitation, of the short-circuit effect and a simplification of the localization of earth faults. However, if other solutions were to be available for the above-mentioned purposes, the structural engineers would be inclined to omit the double rail system.

The present invention now produces a main distribution station and a substation of the above. the type where account has been taken of all the above-mentioned disadvantages of existing installations and the requirements with regard to the gradual expansion with respect to the HV installations as well as to the MV installations.

The main distribution station according to the invention is characterized in that the HV part as well as the MV part comprises at least one multi-phase fed part arranged in such a way that

it can be arranged together with corresponding additional fed parts to form a full feed, in which the HV fed ring is placed axially above the MV fed ring, while the HV transformer is installed to the side of these rings, where each of the HV fed the parts contain an HV circuit-breaker, two busbar parts which are to be connected to each other by means of the circuit-breaker and which both extend over the part of the feeder ring, HV disconnection switches by means of which the two busbar parts can be connected to the HV-fed line and with the HV transformer windings, respectively, device for.connecting the ends of

the rail parts that are not connected to the HV power switch

to corresponding rail end parts to other adjacent fed

in the fed ring, and where the MV feed part comprises a rail part bent along the circumference of a circle, an MV fed circuit breaker able to connect the rail part with the transformer MV winding and to feed the cable, respectively, MV output circuit breakers, each of which is capable of connecting the rail section; with an outgoing MV cable, coupling means for connecting the existing rail section with optional further rail sections spatially adjacent to the existing rail section in the MV fed ring to be formed.

In a preferred embodiment of the main distribution station according to the present invention, one end of the MV rail part is connected to the MV-fed circuit breaker while the MV outgoing circuit breakers are connected uniformly distributed with the rail parts and each of the MV circuit breakers is installed on the outside of the MV-fed ring inside an associated ring part adjacent to the MV rail part.

To one or more additional MV rail part(s)

• is the free end of the existing rail part(s)., which does not

is connected to an MV-fed circuit breaker, connected by means of a connecting circuit breaker or a disconnecting switch to the spatially adjacent end of the additional MV busbar section, the other end of which is connected to the associated MV-fed vacuum circuit breaker and/or the side of the MV-fed circuit breaker to the existing rail section connected to the EV transformer or cable, respectively, is connected to

corresponding sides of an MV-fed circuit breaker to the rail section spatially adjacent to the existing rail section at this end, the other end of which can be connected by means of a vacuum circuit breaker to a further MV rail section spatially adjacent.

A completely MV-fed ring according to the present invention contains a majority of e.g. four busbar sections bent along a part of a circuit in which the connection between two ends face each other in the ring and belonging to two adjacent busbar sections alternatively comprise a switching circuit-breaker or disconnecting switch and two MV-fed circuit-breakers arranged in series, respectively, whose common connection is connected with the high-voltage transformer or the cable, respectively. The intermediate voltage fed ring is further made with several MV earthed switches to earth each of the rail sections

and each one of the outgoing MV cables, respectively.

Apart from the transformers, the entire main distribution station according to the present invention, which has the same capacity as currently existing outdoor main distribution stations, can be installed inside a two-storey tower or a pillar which has a diameter of about 6m and a height of about

About. The MV part is then installed inside the first floor at ground level or fully or partially buried with respect to the incoming and outgoing cables or limitations with

consideration of the height of the buildings, while the high-voltage part is located on the second floor above the medium-voltage part. The foundation can consist of a single pillar or of a steel plate frame which continues in the MV part of the house and which carries the floor to the second floor while the intermediate tension ring is supported from this frame inside the first floor. The high voltage part may be located on a level with the high voltage supply lines

:for the stations on the land side of the high voltage network. In cities where high-voltage cables must be used, large basements are avoided due to the radius curvature of the high-voltage cables.

The required building site of the order of 20 x lOm, which includes two transformers, is very small compared to the above-mentioned common main distribution stations that have overhead lines. This is very important for high-voltage distribution stations that are to be located inside cities that have a high building density. The building can be completely constructed in a factory from prefabricated elements and installation parts. However, installation parts such as the rail parts and switches can also easily be added at any desired time, and thus the possibility is present for a gradual increase of both the high-voltage part and the medium-voltage part. The building materials are reduced to a minimum, while on the other hand something like a main distribution station shaped like a small pillar would hardly be noticed in the countryside or in the cities. With a simultaneous capacity of 40MW, the costs of a main distribution station according to the present invention will be considerably lower than for an above-mentioned main distribution station isolated by means of air.

The inlet device for the lines and the connections to the high-voltage transformers can be constructed as arms in one piece with the building, where said arms carry insulators, the same also applies to the inlet devices for the high-voltage lines. The station thus also serves as a mast.

Instead of the usual double rail system

a rail installation that provides maximum service possibilities such as the double rail system is now used. There will be no need for rails to transfer more than only 75% of the maximum transformer capacity, which is in the case of the open or incomplete ring. In the event of damage to one of the components, the power supply can always continue using the remaining parts in the ring. Circuit breakers which are most often subject to inspection can be easily carried out due to their arrangement inside a circuit or ring part on the outside of the fed ring without blocking any of the wires or transformers. Thanks to the device inside an outwardly enlarging circle or ring sector, the length of the rail is no longer determined by the field's widest component, such as e.g. by a vacuum switch. The length of the rail can thereby be kept as small as possible. Moreover, an extension of the main distribution station tii complete ring instructions is not an immediate necessity. While a single rail will be sufficient in normal stations where the capacity is less than 10 MVA, in the station according to the present invention only a part of each ring will be installed to begin with. In this connection, it should be noted that an extension of the ring is possible while the station is in operation.

In the existing main distribution stations

in which the insulation is carried out by air, one could indeed also gradually expand the high-voltage part with increasing energy consumption, but in that case a much larger surface area had to be available from the beginning to be able to meet the maximum expansion that was expected.

In the case of the main distribution station according to the present invention, the arrangement of the installation parts is further such that, with regard to heat generation, the most heavily loaded parts such as the rails and feeder switches can be very easily heavily cooled by means of a simple cooling unit which thus allows an overload of 30%. Due to the ring-shaped shape, which has a small diameter of around 120cm, the rails are

moreover, extremely short so that there will only be a light generation of heat. The MV installation - will include a minimum

of combustible materials if vacuum circuit breakers are used therein, and if the cables to the components and the installation on

due to their explosive nature, such as gas-producing switches and wet cable terminations, are kept outside the installation and no oil switches are used therein.

The rail parts and the vacuum switches connected thereto in the MS part will preferably be embedded in an insulating material without

any air gap. The outgoing fields of the medium-voltage part can be connected to the medium-voltage busbars in a fixed or extendable manner without any air gap.

All the operating devices for vacuum circuit breakers to earth the rail members and cables will preferably be connected to each of the associated vacuum circuit breakers in such a way that before the earthing circuit breaker can be disconnected

the associated vacuum circuit breaker must be disconnected completely and vice versa. This can be easily achieved by controlling the switches using the same operating mechanism. All additional necessary installation parts such as current transformers, capacitive voltage dividers for voltage indication, connections with the cable end connections can be installed below or close to the rail parts and the whole unit can be placed inside a sheet steel cabinet in the form of a desk that has indication diagrams, readouts -indicators, ammeters and voltmeters. A very compact distribution station has thus been achieved.

On the outside, the housing transformers are arranged on rails for very easy transport, and this is particularly advantageous for displacement and for load adjustment.

The above-mentioned problems at the existing main distribution stations have now been solved by the main distribution station according to the present invention. By means of the compact main distribution station according to the present invention, it is possible in a simple way to apply energy in an existing MV network at many more points than was previously possible. In the case of closed feed circuits, the main distribution station according to the invention constitutes a satisfactory replacement for the double rail system, while both the medium voltage part and the HV part allow a gradual expansion whereby the large investment costs to begin with become redundant.

The invention also includes a substation for distribution of medium voltage not fed by a high voltage part comprising a transformer, but from a medium voltage cable connected somewhere to a main distribution station or to another substation. These substations only comprise the medium voltage part of the main distribution station according to the present invention. Such assumptions allow an MV energy application in places where there is not yet any need for an application from a high-voltage line. If the energy consumption exceeds a certain limit, such a substation can very easily be converted into a main distribution station. For that, you only need to build the second floor and install transformers. In consideration of the insignificant surface area to be reserved, one can easily include in the calculation from the beginning such a design.

The invention will be described in more detail by means of embodiments and with reference to the drawings, where

Figure 1 shows a schematic vertical view of

a main distribution station according to the present invention,

figure 2 schematically shows a cross-section through the high-voltage part of a main distribution station according to the present invention,

figure 3 shows a top view of a partially installed high-voltage part, so-called T-installation of a main distribution station according to the present invention,

figure 4 shows a completely closed supply ^or.corresponds to that in figure 3 for a high-voltage part, a so-called H-installation,

figure 5 shows a top section of the medium voltage part of a main distribution station according to the present invention,

figures 6-9 show expansion possibilities for the medium voltage part of a main distribution station according to the present invention,

Figure 10 shows a partially vertical cross-sectional section through the intermediate tension part along line X-X in Figure 5, and

Figure 11 shows a cross-sectional view of a substation according to the present invention.

Same reference number on the different figures

shows the same parts on both the main station and the substation.

Figure 1 shows a cross section and a partial side section of the main distribution station according to the present invention, where a pillar house 1 is divided into two floors by means of a floor 2 supported by a pillar or frame 3, where the pillar or frame can form the foundation of the main distribution station, but it can also be erected on a separate foundation. The house is . covered with a roof 4. HOUSE 1 has also been equipped with not shown doors, windows and stairs or ladders along the side walls. With a capacity of 40 MVA, the width of the house is approx. 6m and the height approx. About.

On the second floor, the high-voltage part denoted by the reference number 5 is arranged on floor 2, while, on the other hand, the medium-voltage part 6 has been arranged on the first floor

e.g. on a level with the ground. In this example, the intermediate voltage part 6 is listed as a complete ring, such as is only found in a completely finished station, where said ring

is supported by the frame 3 or carried by the bottom of the housing 1. On the outside of the housing two transformers 7 and 8 are indicated.

Figure 2 shows a cross-section through the high-voltage part 5 of the housing and a top section of the transformers 7 and 8. Support arms 9 and 10 have been arranged on the side wall of the housing, where the arms serve for introducing the high-voltage cables 11 and 12, where the cables have been constructed as overhead lines. These support arms 9 and 10 are in one piece with the wall of the house. Three-phase high voltage lines 11 and 12 have been attached to the insulators 13 and 14 from which one connection goes to the suspension insulators 15 and 16, supported by the arms 9 and 10. The suspension insulators are sleeve insulators through which the high voltage is supplied to the high voltage by means of inlet -leaders 17 and 18.

In this complete main distribution station, the high-voltage part 5 comprises three-phase busbar parts 19 - 22 which are connected to each other by means of high-voltage power switches 23 to 26, and which have been installed at the corners of a rectangle. Each of the rail parts 19-22 contains two adjusted rail parts which can also be connected to each other so that there are eight half rail parts in total. -The connections between the three-phase inlet conductor 17 and 18 and the three-phase busbar section 19 and/or 21, respectively, and between the busbar sections of ~each of the sections provided by three-way high-voltage disconnect switches 27 and 29, and which are only indicated schematically at the junction between the busbar conductors, the busbar section and the busbar sections and the rail parts. Similarly, the three-way high-voltage disconnect switches 28 and 30 can connect the rail sections 20 and 22 or the rail parts to the primary high-voltage windings of the transformers 7 and 8, which are located on the outside of the housing 1. As high-voltage circuit breakers, SF6-filled switches can be used.

At the station shown in Figure 1, the connection between the three-way disconnect switches 28 and 29 and the high-voltage transformer's 7 and 8 primary windings is made with embedded conductors denoted by reference numbers 31 and 32. However, this connection can also be made by means of arms corresponding to arms 9 and 10 by means of which the high-voltage lines 11 and 12 have been connected. These arms, not shown in the figures, can similarly be in one piece with the housing 1 and thereby extend in a direction perpendicular to the direction of the shown arms 9 and 10 by means of which the overhead lines of the HS network have been connected.

In Figures 1 and 2, the high-voltage power switches 23 to 26 have only been shown schematically, where the switches include

an operating mechanism located in the vertical housings 33 and

34 in Figure 1. In the bottom part of these housings 33 and 34, switch elements have been arranged for interrupting the connection between the four rail sections.

The power supply in the high-voltage section leads from the high-voltage lines 11 and 12 via the feed-in conductors 17 and 18, the three-way disconnect switches 27 and 29 connected thereto with the two busbar sections 19 and 21. These busbar section ends, i.e. the outer ends of the busbar sections of each section, terminate in the high-voltage eff circuit breakers 23 and 24, and 25 and 26 respectively. The other sides of these circuit breakers have been connected to adjacent parts of the rail sections 20 and 22. These rail sections can be connected by means of three-way disconnect switches 28 and 30 to the embedded conductors 31 and 32 as a driver

to the 7 and 8 primary windings of the high-voltage transformers respectively.

Figures 3 and 4 show expansion possibilities for the high-voltage part in a main distribution station according to the present invention. Figure 3 shows an embodiment in which a transformer may be sufficient for the time being. This is a so-called T-installation. In both arms 9 and 10, in which the voltage lines 11 and 12 again end, where these lines are suspended from the insulators 13 and 14 respectively. With the help of the suspension sleeve insulators, not shown, and likewise not shown lead-in conductors, when the high voltage reaches the schematically shown three-way disconnect switches 27 and 29, in which this incomplete embodiment can form a connection to the rail parts of the half-rail sections 19 and 21. The lead-in conductors 17 and 18 as well as the rail sections 19, 20 and 21 have been placed in gas-filled housings, but can also be insulated in another way . The existing parts of the busbar section 19 and 21 again delimit the circuit breakers 24 and 25. Between these circuit breakers extends a complete busbar section 20 in the center of which again a three-way disconnection switch has been provided at 28, which is able to connect the busbar sections with the supply conductors which leads to the transformer 7. In the present case, this takes place with the help of an arm 35 made in one piece with the building and which has the same construction as the beams 9 and 10. From the bottom side of this arm 35 sleeve insulators have been suspended from which the conductors goes to.the primary winding of the high-voltage transformer. As indicated above, Figure 4 shows a high-voltage part which includes a complete feed, a so-called H-installation. In this example, the rail section 22, like rail section 20 in Figure 3, is connected to the primary winding of the similarly not shown second high-voltage transformer by means of an arm 36 and sleeve-shaped insulators and the conductors pass through these.

The other parts are denoted by the same reference numbers in the following figures.

A ring installation naturally offers maximum possibilities with regard to operation. In the event of a disturbance in one of the components, the energy supply can always take place with the help of the other parts of the ring. The circuit breaker is often inspected with the intention of interruption due to short-circuit currents, and this can be done without blocking any of the lines or transformers. The installation has also been designed so that it can be taken into account in the event of a later installation of a better type of switches.

Figure 5 shows a top section of a medium voltage part according to the present invention. In the center is the column or frame 3 from which the entire intermediate tension section can be supported. Using the reference numbers 37,38,39 and 40, the embedded MV rail sections are shown. These sections have been completely embedded in an insulating material, see figure 10 which shows a vertical cross section along the line X-X in figure 5. In figure 10 the right part, the three phases of the medium voltage rails have been denoted by R, S and T, and all three of these have been embedded in insulating material 50. The rail section 37 in Figure 5, which starts clockwise from the left lower end to the right upper end has been connected with a circuit breaker 41, five outgoing circuit breakers 42 to 46, which lead to outgoing cables and a circuit breaker 47 By means of the feed switch 41, current is supplied to the rail section 37 from the secondary lower. the voltage winding of one of the transformers whose current can be supplied to outgoing cables by means of each of the outgoing switches 42 to 46 to several intermediate voltage fields. The coupling switch 47 makes it possible to connect the rail sections 37 and 40 to each other. The other rail sections 38, 39 and 40 have been constructed in the same manner as rail section 37, but have the difference that the direction of current in rail sections 38 and 40 is opposite to that in sections 37 and 39 assuming any uniform loading of the ring. Sections 37 and 38 are connected to one transformer by means of their feeder switch 41 while rail sections 39 and 40 are connected to the other transformer by means of their feeder switch 41. At each end of the various switches on the side facing away from the rail section there are has been arranged a pipe mechanism 59, shown only schematically, by means of which each switch can be operated. Using the same pipe mechanism, an earth load can also

switch for grounding either one of the rail sections or the

associated outgoing cable be serviced. It is preferred

that the various switches are vacuum switches.

In figures 6,7,8 and 9, expansion possibilities for the MV part of a main distribution station or

a substation according to the present invention, respectively. To begin with, one can start with a rail section according to the embodiment in Figure 6 in which the same reference numbers denote the same parts as in Figure 5. In such a situation, the feeding takes place by means of a feeding cable. In order to create opportunities to ground the feed cable without simultaneously grounding the rail, one of the switches 4 2 to 4 6 is used as a feed switch. The feed switch 41 can then be omitted to begin with. In figure 6 earth load switches have also been shown by means of which the rail section 37 and various cables down to the outgoing vacuum switches 32 to 46 can be earthed. These earthing switches are vacuum load switches and have been designated in the figure using the reference number 48. In figure 7,

where a second rail section 40 has been installed which in the present case requires a second feed cable to which again one of

the right vacuum switches 42 to 46 are connected. In case of lapse

of one of the feeds, the corresponding rail section can be fed by closing the switching switch 4 7 by means of the non-disrupted rail section.

Further expansion possibilities have been indicated in Figures 8 and 9. For the sake of clarity, most of the reference numbers for the various vacuum switches have been omitted in Figures 8 and 9.

Figure 8 shows a further extension by means of a third rail section 39. In this case, a transformer performs the feeding, and for this reason both right vacuum-fed switches 41 are connected together with the transformer. To guarantee undisturbed feeding, e.g. at the transformer feed, the existing cable feed to sections 37 and 40 can be maintained. Optionally, an outgoing field can be used for the rail section 39 to perform this rail section with the cable feed.

Finally, Figure 9 shows the complete MV part of a main distribution station or substation according to

lying invention.

Thereby, a second transformer has been installed so that the entire installation can be fed using transformers. The feed fields used for the cable feed can then again be recognized as outgoing fields.

From these figures, the gradual expansion possibility of the MV part in a main distribution situation according to the invention is clearly evident, but the same also applies to a substation according to the present invention. The intermediate voltage feeder containing rail sections 37 to 40 can be gradually complemented depending on increasing energy demand within an area to be fed. To begin with, only one rail section will be sufficient and the switching switch 47 as well as the feed switch 41 can be omitted. In case of increasing energy consumption, a second feeder cable will be connected to the distribution station and a further rail section will be installed, in figure 7 rail section 40. It should be noted, moreover, that this extension is not limited to the form shown in figure

7. Instead of the rail section 40, it can also be installed

a rail section 38 as a second section, see figure 9.1

in this case, both sections 37 and 38 can be fed either by a transformer or by means of cables. Figure 8 shows the next step to the expansion of the medium voltage section after the step shown in Figure 7, while Figure 9 shows the fully installed medium voltage installation.

For the medium-voltage part, it applies that due to the negligible rail length, heat production is at a minimum. The rail sections 37 to 40, together with the connection and its coupling devices, can be completely embedded in a plant. The ring-like device makes powerful cooling very feasible. The switch 47 between two adjacent rail sections inside the feed ring as well as the outer vacuum switches serves for safety monitoring of the rails, but also serves as a protection switch for the transformer. These circuit breakers as well as the rails must not carry more current than 75% of the maximum transformer load. It will be self-evident that all vacuum circuit breakers are designed as three-phase circuit breakers in this case as well. Figure 10 shows the arrangement of vacuum effect the switches and load switches for grounding cables and rail sections to the medium voltage section in further detail. The figure shows a cross-section through an outgoing field, where the outgoing field also includes the switch 44 in Figure 5. On the right side, this vacuum switch 44 is connected with a phase to the rail section 37. The rail 49 of this rail section has been completely embedded in an insulating material 50 which is also clearly evident from figure 5 which has been made with a hollow part 51 which protrudes in the left direction in which a box-like end is adapted to a housing 5 2 of insulating material. Inside this housing 52, the outgoing vacuum circuit breaker 44 has been inserted. A current conductor 53 runs from this circuit breaker in the right direction through the hollow part 51 into an opening in the rail 49. Between the inner wall of the hollow part 51 and the outer wall of the neck-like right end of the housing 52 has been provided with a sealing material.

The housing 52 is closed on the left side by a second housing 54 of insulating material in which operating devices for the vacuum switch 44 and the earthing switch 48 have been placed.

The movable stray conductor 64 of the switch 4 4 can move a

of the switch contacts for connecting and disconnecting the switch 44. On the current conductor 64, the connecting device 55 for outgoing cable 56 to a field has been shown. This cable is likewise connected to the left movable current conductor 65 to the earthing switch 48 by means of the connection device 57. The right current conductor to this earthing switch has been connected to the ground rail 58. The left movable current conductor 65 to the switch 48 is also connected to the operating device in the housing 54. Be The device in question has been connected to a pipe mechanism 59 which can be switched by means of a selector button 60. By moving the selector button in the axial direction, either the vacuum switch 44 or the vacuum switch 48 can be operated so that either the cable 56 is connected to the rail 49 or the cable 56 is grounded. The operating device for the alternating operation of the two vacuum circuit breakers can also be realized in a very simple way by means of the pipe mechanism which thus performs the necessary mechanical locking between the circuit breaker and the earthing switch in a simple way.

In Figure 10, the vacuum feed circuit breakers and vacuum load earthing switches for the rails of the phases S and T of the same field have only been shown schematically. It is clear that the construction thereof corresponds to the embodiment shown in the cross-section in figure 10.

Figure 10 has likewise shown the drawing device for the rails and the vacuum switch as well as the operating device for the vacuum switches. The entire structure has been placed in a desk 61, a raised part 62, which e.g. can be used to accommodate ammeters and voltmeters 63 as well as alarm devices. For each of the rail sections 37 to 40, a desk can be used which has a bend that runs along the rail section.

As can be seen from figure 10 and also from figure 5, the rails can be made very short due to the fact that the vacuum switches are connected to these rails by means of their narrow ends. This is the reason why a shortening of the rail length is only possible when using a circular fed rail that has the fields located on the outside. The parts of the vacuum switches that have a greater width are at a greater distance from the rails. The removal of the switches can be done very easily by pulling the switches away from the rails.

Figure 11 shows a cross-section of a substation according to the invention. This basement only includes the first floor, which includes the parts located therein of the main distribution station described above. An important advantage of a substation according to the present invention is that it can be supplemented very easily to form a main distribution station at a later time. To carry this out, one only needs the frame 3 which is shown dotted in Figure 11 to extend it to the higher part. On top of this frame, a floor has been built on which the high-voltage part can then be placed. Naturally, the house must also be made higher. The power supply to the high-voltage part can then be carried out by means of an overhead line or also by means of a high-voltage cable. In the latter case, an additional room for the transformers would not be added because the house is only made higher.

The understanding includes a house 1 for which the foundation has been shown in the drawings as well as the rooms in which the cable and connection 62 for the different fields are present. The intermediate voltage part 6 has also been constructed in the same way as shown in Figures 5 to 10. The substation according to Figure 11 can also be partially or completely buried in the ground. This can e.g. be beneficial if an inadequate

height is available for the extension of a complete main distribution station built at ground level.

The time at which you want to convert a substation

to a main distribution station is dependent on economic aspects determined by the growth. With regard to previously known main distribution stations, one will start with expansion investments

in the intermediate voltage section for a longer time in which

if the initial capacity of the HV part of the main distribution stas ion will be very high. When starting from a substation according to the present invention which is shown in Figure 11, one will be much more inclined to reshape such a substation. station to a main distribution station in that, according to the invention, it is also adapted for an HV part. Neither the main distribution station nor the substation must be built to their full capacity from the start. The MV feed cables for the substation can be used as outgoing cables, for example as ring cables for network stations. These cables can too

be used as a service for MV bearing points from the thus created main distribution station. The vacuum switches for that

The feed cables eliminated in this way can then again be used<;>: for outgoing cables.

The invention thus as described above is of course not limited to the embodiments described and'. shown in the drawings, but naturally includes modifications and variations that are possible without deviating from the idea and purpose of the present invention.

Claims (20)

1. Main distribution station comprising a high-voltage part (HV) and a medium-voltage part (MV) and at least one high-voltage transformer connected between said parts, characterized in that the HV part as well as the MV part comprise at least one multiphase fed sector mounted on such a way that it can be arranged together with corresponding additional feed sectors to form a complete fed ring, in which the HV fed ring is located axially above the MV fed ring, while the high voltage transformer is installed adjacent to these rings, each one of the HV-fed sectors consists of an HV circuit-breaker, two busbar sections to be connected to each other by circuit-breaker and both of which span the part of the fed ring, HV disconnecting switches by means of which the two busbar sections can be connected with the HV-fed line and with the transformer's HV winding, respectively, device to prevent the ends of the busbar sections, which are not connected to The HV circuit-breaker, with corresponding ends to the busbar sections of other adjacent feeder sectors in the feeder ring,. and the MV-fed sector consisting of a rail section bent along a circumferential part of a circle, an MV-fed circuit breaker capable of connecting the rail section to the MV angles of the transformer or to a fed cable, respectively, MV outgoing circuit breakers, each one of which is capable of connecting the rail section to an outgoing MV cable, coupling means for connecting the existing rail section to optional additional rail sections spatially adjacent to the existing rail section in the MV fed ring to be formed. 2. Main distribution station according to claim 1 made with a number of feeding sectors, characterized in that the HV disconnection switch is a three-way switch by means of which the HV-fed line and the transformer's HV winding, respectively, can be connected to one of the parts of the rail the sector, which faces each other or to both parts and by means of which both parts can be connected to each other. 3. Main distribution station according to claim 1 or 2, characterized in that one end of the MV rail section is connected to the MV-fed circuit-breaker and that the MV outgoing circuit-breakers are connected equally distributed with the MV busbar section while each of the MV circuit-breakers is installed on the outside of the MV-fed ring inside a connecting rig sector belonging to the MV- the rail section. 4. Main distribution station according to claim 1, 2 or 3, characterized by a plurality of MV earth or load breakers to earth each. one of the MV busbars and each of the outgoing MV cables, respectively, 5. Main distribution station according to claim 3, characterized in that the free ends of an existing MV rail section(s), not connected to the MV-fed circuit breaker of one or more additional MV rail section(s), are connected by means of a connecting circuit-breaker to the spatially adjacent end of the additional MV busbar section, the other end of which is connected to the associated MV-fed circuit breaker and/or side of the -MV-fed circuit breaker to the existing MV busbar section connected HV transformer or cable , respectively, are connected to the corresponding side of an MV- fed circuit breaker to the spatially adjacent rail section at this end of the existing MV rail section, if • the other end can be connected by means of a circuit breaker to a further spatially adjacent MV rail section. . 6. Main distribution station according to claim 5, characterized in that the additional MV-fed circuit breakers and the coupling circuit breaker are installed inside an outer ring sector adjacent to the rail section. 7. The main distribution station according to any of the preceding claims, characterized in that all the rail sections and circuit breakers of the MV^ parts have been embedded in an insulating material. 8. Main distribution station according to: any of the preceding requirements, characterized in that all the MV switches are vacuum switches. 9. Main distribution station according to any one of the preceding claims, characterized in that a complete HV-fed ring contains four HV circuit-breakers installed at the corners of a rectangle, where the circuit-breakers are connected to each other by means of straight rail sections and that the HV disconnection switches are connected to the middle parts of the rail six ions. 10. Main distribution station according to any one of the preceding claims, characterized in that a complete MV-fed ring contains a plurality of rail six ions bent along the circumferential part of a circuit, in which the connection between two ends facing each other in the ring and belonging to two MV rail sections adjacent to each other in the ring alternately comprise a switching circuit-breaker or two MV-fed circuit-breakers arranged in series, respectively, whose common connections connected with HV transformer. 11. Main distribution station according to any of the preceding claims, characterized in that the high-voltage part and the medium-voltage part are located inside a tower-like two-story house in which the high-voltage part is installed inside the second floor and the medium-voltage part is installed inside the first floor, where both deleneer carried by a central frame arranged axially with respect to the feeds inside the house, where the frame carries the floor to the second floor and serves as a suspension for the MV-fed ring. 12. Substation for the distribution of medium voltage, characterized in that at least one multi-phase fed sector is installed on such a one. in such a way that it can be arranged together with corresponding additional feeder sectors to form a complete feeder in which each sector consists of a rail section bent along the circumference of a circle, a fed circuit breaker capable of connecting the rail section with an MV fed cable, outgoing circuit breakers which is capable of being connected with the rail section of an outgoing field, coupling device for connecting the existing rail section with further rail sections spatially adjacent to the existing rail section in the feed ring to be formed. 13. Substation according to claim 12, characterized in that one end of the rail section is connected to a fed circuit breaker and that the outgoing circuit breakers are connected in an even distribution with the rail section, where each one of the circuit breakers is installed on the outside of the feed ring into an associated ring sector adjacent to the rail section . 14. Substation according to claim 12 or 13, characterized by a plurality of grounded load switches to ground each one of the rail sections and . each of the outgoing cables, respectively. 15. Substation according to claim 13, characterized in that the free ends of existing rails: section(s) not connected with fed circuit breakers until one or more additional busbar section(s) are connected by using a circuit breaker with spatially adjacent end. to the further section, the other end of which is connected to the associated fed circuit-breaker and/or the side of the fed circuit-breaker to the existing rail section connected with the MV feeder cable is connected to the corresponding side of the fed circuit-breaker to the rail section spatially adjacent at its end of the rail section, whose other end can be connected by means of a coupling circuit breaker to a further spatially adjacent rail section. 16. Substation according to claim 15, characterized in that the further fed circuit breakers and coupling circuit breakers are installed inside an outer ring sector adjacent to the rail section. 17. Substation according to any one of claims 12-16, characterized in that all the rail sections and switches have been embedded in an insulating material. 18. Substation according to any one of claims 12-17, characterized in that all the switches are vacuum switches. 19. Substation according to any one of claims 12-18, characterized in that a complete feed has several rail sections bent along the peripheral part of a circuit in which the connection between two ends facing each other in the ring and belonging to adjacent rail sections alternatively comprises a switching circuit breaker and two .fed circuit breakers arranged in series, whose common connection is connected to the MV fed cable. 20. Substation according to any one of claims 12-19, characterized in that the fed ring is installed inside a circular housing in which the ring is carried by means of a central frame mounted axially with respect to the ring inside the housing.