DE3642108A1 - Switching installation for distributing electrical power, and a method for operating the switching installation - Google Patents

Abstract

This medium-voltage or high-voltage switching installation has a main busbar (3) and two auxiliary busbars (1, 2). Each auxiliary busbar (1, 2) is connected to the main busbar (3) via a power switch (circuit breaker) or load-interrupter switch (LS1, LS2). The supply line or lines (4) and the outlet lines (5, 6) are in each case connected to all three busbars (1, 2, 3) via interrupter switches (T01, T02, T03, T11, T12, T13, T21, T22, T23). If the current flow (load current or short-circuit current) in one of the supply or outlet lines is intended to be interrupted, this line is initially commutated without interruption onto an auxiliary busbar and the interrupter connection of this line to the main busbar is then interrupted. The current flow through the power switch or load-interrupter switch associated with this auxiliary busbar is subsequently interrupted. The current flow in all the other lines is not influenced by this process. A line is switched on in a similar manner, likewise by commutating onto an auxiliary busbar. If, independently of this, it is necessary to connect or disconnect a further current to or from another line at the same time, the first line to be connected is connected to one auxiliary busbar, and the second circuit to the other auxiliary busbar. <IMAGE>

Description

The invention relates to a switchgear for Distribution of electrical energy according to the generic term of claim 1 and a method for operating the Switchgear.

Such a switchgear for electrical distribution Energy and such a method of operating the Switchgear are for example from DE-OS 35 06 383 known. The switchgear described there has two Busbars and a tie switch on, which in Ver connection with multi-position disconnectors the power and switching operations. It is essential here the use of a multi-position disconnector, the the supply lines or cable channels without interruption switches to the busbar systems. However, it is not possible a short-circuit current or load current at the same time or overlapping with another Switch off switching process independently of this.

Switchgear are nodes for transmission and Ver division of electrical energy. In these nodes are feed lines and Outgoing lines connected together. The task of Switchgear (circuit breaker or load switch) within the switchgear is to switch on the operating currents or switch off and interrupt short-circuit currents. For medium voltage and high voltage switchgear it is common in many cases to use the switchgear to build one or more busbars and in correspond to each feed line and each outgoing line A load switch depending on the currents to be switched or to arrange a circuit breaker.

The costs for a switchgear constructed in this way become too a large part by the cost of switching devices true, especially if in every outgoing line and a circuit breaker is present for each feed line that is. Another feature one with a single Busbar built system is that the disposition Ability of a departure through the availability of this Outgoing assigned circuit breaker or load switch ters is essentially determined.

Arrangements of switchgear are generally known which increases availability through installation from more than one busbar. At such multiple busbar assemblies can Sam milschienen out as so-called auxiliary busbars leads. The need for every exit or everyone Feed in at least one load or power scarf This does not eliminate having to assign them. In fact, some of these require multiple collections rail arrangements even more than a performance scarf ter per outlet or per infeed.  

Concepts have therefore been proposed in which one with fewer than one switching device per outlet or Feed comes in, and yet on every line Can switch load or short-circuit currents.

In DE patent application K 11 405 VIIId / 21c, known makes 9 Aug. 1956, for example it is suggested the tie switch in a double busbar arrangement use as a central circuit breaker. In this arrangement one of the two busbars is called Main busbar used, with that in normal operation (no switching process) via the corresponding disconnector all inlets and outlets are connected. At the Ab switching the current of a line is this first without interruption by pressing the Line assigned disconnector to the second, as an auxiliary busbar designed and with the main busbar Sam connected by the closed dome switch Melschiene switched, and the power interruption then then carried out by the tie switch. With a switching operation it is with this arrangement but not possible that through the tie switch short flowing simultaneously in another line final current switched off in the required short time can be. It is described in the above patent message proposed in each feed line and each outgoing line a fuse for short-circuit current to arrange an interruption. For most switchgear, especially in the high voltage level, is one However, solution is not acceptable.

In EP-A-01 26 882 there is also a double collection Rail arrangement with a tie switch as the central one Switch suggested only in each feed line a circuit breaker is arranged. In  the outgoing lines is not a power or load scarf ter provided. In the event of a short circuit, the power Infeed switch open. On a backup in every infeed and outgoing line can with the this solution can be dispensed with. Disadvantage with this solution is, however, that in the event of a short in an outgoing circuit for a short time the load flow in all other outgoers must also be interrupted. That is also in the unacceptable in most cases.

On this basis, the invention is based on the object de, a switchgear for the distribution of electrical energy gie of the type mentioned above, which a selek tives, uninterrupted, simultaneous or time overlapping switching on and off of feed and Outgoing lines using as little load or circuit breaker enabled. Furthermore, a Procedure for operating the switchgear specified will.

This task is related to the arrangement with the features of the preamble according to the invention by those specified in the characterizing part of claim 1 Features solved.

The task is carried out with regard to the procedure by the in solved the claims 6 to 8 characterized features.

The advantages that can be achieved with the invention are special in that as a result of the proposed arrangement with three busbars and central load or Circuit breakers between as the main busbar operated busbar and the two auxiliary bus seemed despite the reduced, minimal performance switch effort a short-circuit current or load current at the same time or overlapping with another  Switching process can be switched off independently of this can. In the event of a short circuit in an Ab the load flow did not go down in other outlets be broken. In the event of a short circuit, short is advantageous interruptions (KU circuits) possible. In the ver connections of the feed lines and outgoing lines the three busbars advantageously do not need any load or circuit breakers are provided.

Advantageous embodiments of the invention are in the Subclaims marked.

The invention is based on the in the drawing Illustrations illustrated embodiments, at between the main busbar and the auxiliary seed a bus circuit breaker is arranged or two circuit breakers are arranged.

Show it:

Fig. 1 is a Triple busbar assembly lines with a supply line and two disposal,

Fig. 2 shows the switching states of interest separation and power switches in circuit from an outlet line,

Fig. 3 shows the switching states of interest separation and circuit breakers in a circuit of an output line,

Fig. 4 shows the switching states of interest separation and power switches at a time overlapping elimination of two outgoing lines,

Fig. 5 to 8 a multi-position disconnector in ver different switching states,

Fig. 9 shows a variant for the redundant Dreifachsam melschienenanordnung according to Fig. 1,

Fig. 10 shows a further variant of the triple redundant bus bar assembly of FIG. 1.

In Fig. 1, a triple busbar arrangement is shown with one feed and two outgoing lines. In particular, two auxiliary busbars 1 and 2 and a main busbar 3 are provided, wherein the first auxiliary busbar 1 via a first circuit breaker LS 1 and the second auxiliary busbar via a second circuit breaker LS 2 with the main busbar 3 are ver bindable. The feed line 4 can be connected to the first auxiliary busbar 1 or to the second auxiliary busbar 2 or to the main busbar 3 via disconnectors (commutation disconnectors) T 01 or T 02 or T 03 . The first outgoing line 5 can be connected via disconnector T 11 or T 12 or T 13 to the first auxiliary busbar 1 or to the second auxiliary busbar 2 or to the main busbar 3 . The second outgoing line 6 can be connected via isolating switch T 21 or T 22 or T 23 to the first auxiliary bus bar 1 or to the second auxiliary bus bar 2 or to the main bus bar 3 .

In the arrangement shown, each output and each feed line can therefore be connected to three busbars via isolating switches, with normal operation (no switching operation) only connecting to the main busbar 3 , ie isolating switches T 03 , T 13 , T 23 are closed . The two auxiliary busbars 1 and 2 are connected to the main busbar 3 via the circuit breakers LS 1 and LS 2 closed during normal operation.

In the exemplary embodiment there are only one feed and two outgoing lines are shown, but it can be vorese supply lines and outgoing lines hen.

If the current flow (load current or short-circuit current) to be interrupted in one of the lines 4 , 5 or 6 , the corresponding line is first uninterruptedly commutated to an auxiliary busbar 1 or 2 and then the isolating connection of this line to the main busbar 3 is interrupted. Then the current flow is interrupted by the load or circuit breaker associated with this auxiliary busbar. The current flow in all other lines is not affected by this process.

As a first example of this, the disconnection (from circuit) of the first outgoing line 5 via the auxiliary busbar 2 is considered. In Fig. 2, the switching states of the circuit breaker T 11 , T 12 , T 13 and circuit breaker LS 1 , LS 2 of interest are shown for this example. The number "0" symbolizes the "off" state ("open") and the number "1" the "on" state ("closed") of the switch. From the output switching state a corresponds to normal operation, ie the switches T 03 , T 13 , T 23 , LS 1 , LS 2 are closed and all other switches are open.

At time t ₀ , the switch-off of the outgoing line 5 begins. At time t ₁ , the disconnector T 12 is closed (switching state b ), ie the outgoing line 5 is now simultaneously connected to the auxiliary busbar 2 and the main busbar 3 , and the current flow into the outgoing line 5 is divided into a current via T 13 and one Current via LS 2 - T 12 . At time t ₂ , the isolating switch T 13 is opened (switching state c ), ie the outgoing line 5 is now only connected to the auxiliary busbar 2 and the current forcibly flows into the outgoing line 5 via LS 2 - T 12 .

At time t ₃ , the circuit breaker LS 2 is opened (switching state d ) and thus the current flow in the output line 5 is interrupted. At time t ₄ , the disconnector T 12 is opened (switching state e ), ie the outgoing line 5 is now separated from all busbars 1 , 2 , 3 . At time t ₅ , the circuit breaker LS 2 is closed again (switching state f ) so that the arrangement is available for further switching operations. At the time t ₆ , the switch-off of the output line 5 is ended. The periods between t ₀ and t ₁ and between t ₅ and t ₆ are due to the switching delays (switch-on delay, switch-off delay) between the switching command and the switching version.

As a second example, the activation (connection) of the first outgoing line 5 via the auxiliary busbar 2 is considered. In Fig. 3, the switching states of the interesting isolating switch T 11 , T 12 , T 13 and Lei circuit breaker LS 1 , LS 2 are shown for this example. In the initial switching state, the switches T 03 , T 23 , LS 1 , LS 2 are closed and all other switches are open. At time t ₇, the outgoing line 5 starts to be switched on. For Zeitppnkt t _8, the power switch LS 2 is open and thus the auxiliary bus bar 2 is separated from the main busbar. 3 At time t ₉ , the disconnector T 12 is closed, that is, the output line 5 is connected to the auxiliary busbar 2 . At time t ₁₀ , the circuit breaker LS 2 is closed, ie main busbar 3 and auxiliary busbar 2 are connected and there is a current flow from the main busbar 3 via LS 2 and T 12 into the outgoing line 5 .

At time t ₁₁ , the disconnector T 13 is closed, ie the main busbar 3 is connected directly to the outgoing line 5 , resulting in an additional current flow from the main busbar 3 via T 13 directly into the outgoing line 5 . At time t ₁₂ , the disconnector T 12 is opened again, ie the current flow via LS 2 and T 12 into the outgoing line 5 is interrupted. At the time t ₁₃ the turn-on of the outgoing line 5 is ended. The periods between t ₇ and t ₈ and between t ₁₂ and t ₁₃ are caused by switching delays.

If switching on or off at the same time further current (primarily the switching off of a short current) on another line is necessary, so it can be there regardless of the first switching operation by happening the same procedure with commutation tion is applied to the further auxiliary busbar. Both switching operations are independent of each other and do not affect each other.

As an example of this, the time-overlapping circuit (shutdown) of the first outgoing line 5 via the second auxiliary busbar 2 and the second outgoing line 6 via the first auxiliary busbar 1 is considered. In Fig. 4 the switching states of the isolating switches T 12 , T 13 , T 21 , T 23 and power switches LS 1 , LS 2 are shown for this example. To go from a switching state in which the isolating switch T 03 , T 13 , T 23 and the circuit breaker LS 1 , LS 2 are closed and the other switches are open. Currents flow from the feed line 4 into the main bus bar 3 and from the main bus bar 3 into the outgoing lines 5 , 6 .

Shortly before the time t ₁₄ , the switching-off process of the outgoing line 5 begins. For this purpose, the switch T 12 is closed at time t ₁₄ , ie the outgoing line 5 is placed on the auxiliary busbar 2 and there is an additional current flow from the main busbar 3 via LS 2 , T 12 in the outgoing line 5th At time t ₁₅ , the disconnector T 13 is opened, where the direct current flow from the main busbar 3 via T 13 to the outgoing line 5 is interrupted.

Shortly before the time t ₁₆ , the time-overturning switch-off process of the outgoing line 6 begins. For this purpose, the disconnector T 21 is closed at time t ₁₆ , ie the outgoing line 6 is placed on the auxiliary busbar 1 and there is an additional current flow from the main busbar 3 via LS 1 , T 21 into the outgoing line 6 . At time t ₁₇ , the power switch LS 2 is opened, whereby the current flowing into the outgoing line 5 is interrupted. At time t ₁₈ , the disconnector T 23 is opened, ie the direct current flow from the main bus 3 to the Abgangslei device 6 is interrupted.

At time t ₁₉ , the circuit breaker T 12 is opened, whereby the outgoing line 5 is completely separated from all collecting rails 1 , 2 , 3 . At time t ₂₀ , the circuit breaker LS 1 is opened, ie the current flowing from the main bus bar 3 via auxiliary bus bar 1 and LS 1 - T 21 is interrupted. At the time t ₂₁, the circuit breaker LS 2 is closed, whereby the disconnection of the outgoing line 5 is finished.

At time t ₂₂ , the disconnector T 21 is opened, ie the outgoing line 6 is completely separated from the busbars 1 , 2 , 3 . At the time t ₂₃ the circuit breaker LS 1 is closed, whereby the switch-off device of the outgoing line 6 is ended. The system is available for further switching operations.

The switchgear is technically implemented particularly cheap in gas-insulated systems with small Construction volume. In such plants are because of the low Isolation distances multi-position isolators as well as combined te isolator earthing possible. The required for the system three isolators per outgoing line or per feed line can be advantageous as a multi-position Execute disconnectors with only one drive where the Possibility of uninterrupted commutation of a Load or short-circuit current from a busbar the other (from the main busbar to an auxiliary busbar and vice versa) must be given.

In Figs. 5 to 8 such Mehrstellungskom is set mutierungstrenner in different switching states are. The multi-position isolator 12 has three fixed switching contacts 7 , 8 , 9 and a movable switching contact 10 . A single drive 11 is used to set the various switching states with the help of the movable switching contact 10 . The fixed switching contacts 7 or 8 or 9 are connected to auxiliary busbar 1 or auxiliary busbar 2 or main busbar 3 . A feed or outgoing line is connected to the movable switching contact 10 .

The switching states of the multi-position isolator shown in FIGS. 5 to 8 correspond to those dealt with under FIG. 2 , states which occur when the outgoing line 5 is switched off via the busbar 2 . He sets the multi-position isolator 12 shown, the disconnector T 11 , T 12 , T 13th The movable switch contact 10 of the multi-position isolator 12 is connected to the outgoing line 5 in this example. In Fig. 5 the switching state a is shown in FIG. 2, in which the movable switching contact 10 of the multi-position isolator 12 contacts the fixed switching contact 9 and thus connects the outgoing line 5 with the main busbar 3 . In Fig. 6, the switching state b is shown in FIG. 2 Darge, in which the movable switch contact 10 of the multi-position disconnector 12 simultaneously contacts both fixed switch contacts 8 , 9 and thus simultaneously connects the outgoing line 5 with the auxiliary busbar 2 and the main busbar 3 .

In Fig. 7, the SchaItzustände 2, c and d of FIG. Shown in which the movable switching contact 10 of the multi-position diverter 12 contacts only the stationary switch contact 8 and the outgoing line connects to the auxiliary bus bar 2 5. FIG. 8 shows the switching states e , f according to FIG. 2, in which the movable switching contact 10 does not make any fixed contact with the switching contact and the outgoing line 5 is consequently separated from all three busbars.

To increase the reliability or the availability of the power supply, an additional redundant connection of the main busbar 3 can be made via a circuit breaker with the two auxiliary busbars 1 , 2 in the system. With such an arrangement, a very high availability can be achieved for each outgoing line, and at the same time, such an arrangement can be constructed more cost-effectively than systems with one circuit breaker per outgoing line and feed line because of the few load or power switches required.

FIG. 9 shows a redundant variant of the triple busbar arrangement according to FIG. 1 as an example. In addition to the arrangement shown in FIG. 1, the main busbar 3 via a further circuit breaker LS 3 and two isolating switches T 3 and T 3 'with the auxiliary busbar 1 and via a further circuit breaker LS 4 and two isolating switches T 4 and T 4 ' with the Auxiliary busbar 2 connected. Between circuit breaker LS 1 and auxiliary busbar 1 or circuit breaker LS 2 and auxiliary busbar 2 , two additional disconnectors T 1 and T 1 'or T 2 and T 2 ' are arranged. The rest of the arrangement is as described under Fig. 1. Any number of additional feed and outlet lines can be provided.

The switching state shown in Fig. 9 corresponds to normal operation, that is, the disconnector T 03 , T 13 , T 1 , T 2 , T 1 ', T 2 ' and the circuit breaker LS 1 , LS 2 are closed and the other switches are open . In the event of failure or maintenance of the circuit breaker LS 1 , the disconnectors T 3 and T 3 'and then the circuit breaker LS 3 are closed. Then the circuit breakers T 1 and T 1 'can be opened and the circuit breaker LS 1 serviced, repaired or replaced. In the event of failure or maintenance of the circuit breaker LS 2 , the disconnectors T 4 and T 4 'and then the circuit breaker LS 4 are closed. Then the disconnector T 2 and T 2 'can be opened and the circuit breaker LS 2 serviced, repaired or replaced.

A further redundant variant of the triple busbar arrangement is shown in FIG. 10. Instead of each of the two circuit breakers LS 1 or LS 2 , a second circuit breaker LS 3 or LS 4 can be connected in parallel, as in FIG. 9, in this arrangement only a single additional circuit breaker LS 3 with associated disconnectors available. In addition, a further isolating switch T 3 '' is provided between the auxiliary busbar 2 and the connection point of circuit breaker LS 3 and isolating switch T 3 (the isolating switch T 3 on the other hand being connected to the auxiliary busbar 1 ). The additional power switch LS 3 can be lelgeschaltet paral entwe 2 by closing the circuit breaker T 3 and T 3 'switches the power switch LS 1 or by closing the separator T 3' and t 3 '' to the circuit breaker CB.

With the arrangement according to FIG. 10, it is thus possible to continue the proper system operation by connecting the circuit breaker LS 3 in the event of a fault or during maintenance of one of the circuit breakers LS 1 or LS 2 .

The coordination of the switching devices (disconnectors and circuit breakers), the selection of the auxiliary busbar used for Stromkommutie tion and the connection of the redundant load or circuit breaker in the event of a device failure is preferably controlled by a central switchgear computer 13 . This switchgear computer 13 and the signal connections to the individual switches are shown in dashed lines in Fig. 1, 9 and 10.

Claims (9)

1. Switchgear for the distribution of electrical energy, in particular medium-voltage or high-voltage switchgear, with a main busbar and at least one first auxiliary busbar connected to it via a circuit breaker or load switch, where the outgoing lines and the feed line (s) are omitted under load or circuit breakers or short-circuit fuses are only connected to the main and the first auxiliary busbar via isolating switches, characterized in that a second auxiliary busbar ( 2 ) is provided which is connected to the main busbar via a circuit breaker or load switch (LS 2 ) ( 3 ) and via isolating switches ( T 02 , T 12 , T 22 ) to the outgoing lines ( 5 , 6 ) and feed line (s) ( 4 ). 2. Switchgear according to claim 1, characterized in that in each case between a circuit breaker or load switch (LS 1 , LS 2 ) and the main busbar ( 3 ) or the auxiliary busbars ( 1 , 2 ), a disconnector ( T 1 , T 1 ', T 2 , T 2 ') is arranged. 3. Switchgear according to claims 1 and 2, characterized in that parallel to each of a circuit breaker or load switch (LS 1 , LS 2 ) and two associated isolating switches ( T 1 , T 1 ', T 2 , T 2 ') Existing Anord voltage each a redundant circuit breaker (LS 3 , LS 4 ) with two associated disconnectors ( T 3 , T 3 ', T 4 , T 4 ') is vorgese hen. 4. Switchgear according to claims 1 and 2, characterized in that parallel to the connected to the first auxiliary busbar ( 1 ), from a circuit breaker or load switch (LS 1 ) and two associated isolating switches ( T 1 , T 1 ' ) Existing arrangement, a redundant circuit breaker (LS 3 ) with two associated disconnectors ( T 3 , T 3 ') is provided and that there is another disconnector ( T 3 '') between the second auxiliary busbar ( 2 ) and the connection point of the redundant Circuit breaker (LS 3 ) with the isolating switch ( T 3 ) leading to the first auxiliary busbar ( 1 ). 5. Switchgear according to one of claims 1 to 4, characterized in that the connection of an output line ( 5 , 6 ) or a feed line ( 4 ) with the three busbars ( 1 , 2 , 3 ) via isolating switches by a single multi-position isolator ( 12 ) takes place. 6. Procedure for operating the switchgear according to An saying 1, characterized in that for switching off an infeed or outgoing line initially this lei by closing one between an auxiliary collection rail and the line arranged disconnector this auxiliary busbar is placed, then the Disconnector between the line and the main collector rail is opened, then the circuit breaker or Load switch between the auxiliary busbar and the Main busbar is opened, then the Disconnector between the line and the auxiliary collector rail is opened and finally the performance switch or load switch between auxiliary busbar and the main busbar is closed again.   7. Procedure for operating the switchgear according to An saying 1, characterized in that for activation an infeed or outgoing line first of all the lei switch or load switch between an auxiliary busbar and the main busbar is opened, then the disconnector between these auxiliary seeds Melschiene and the line is closed, then the Circuit breaker or load switch closed again then the disconnector between the Lei device and the main busbar is opened and closed the isolating switch between the line and the auxiliary busbar is opened again. 8. The method according to claims 6 and / or 7, since characterized in that at the same time or overlapping switching on or off of two lines the first line to one and the second line be placed on the other auxiliary busbar. 9. The method according to any one of claims 6 to 8, there characterized in that the coordination of the separation switches and circuit breakers or load switches, the Selection of the auxiliary collection used for current commutation rail and, if necessary, switching on a redun danten circuit breaker or load switch in case of failure of a circuit breaker or load switch by one central switchgear computer can be controlled.