NL8400150A - METHOD AND APPARATUS FOR AUTOMATICALLY LOCKING A BREAKER SWITCH NEAR A FAULT - Google Patents

Description

* it. "· N / 31847-dV / f.

Method and device for automatically blocking a circuit breaker located near a fault location.

The invention relates to a method for automatically blocking an interrupter switch located close to a fault location for switching off the load, in particular at stations with two input lines, each input line being provided with an electrical switching element, for example an interrupter switch for switching off the load, which opens when a control voltage drops for more than a predetermined period, and closes when the recovery of the control voltage takes longer than a predetermined period, as well as on a device for applying this method she.

In the event of faults in a lead loop or an open branch, comprising a number of network stations arranged in sequence, each individual network station is successively tested in that, viewed in the feed direction, the reverse electrical switch opens, while the forward electrical switch and the switch between the power supply line and 20 closes the network drive. If everything works, continue with the next network drive and repeat the same procedure. When the network station behind which the fault is located has been reached and the fault section of the line section is turned on, the switch at the power point will immediately turn off the power for the entire loop section and consequently also for those network stations, which were found to operate error-free.

At this time, the breaker switch to the faulted line section is released to open and be locked and the switch can be turned back on and power the network stations on the examined faultless line sections. If it is an open branch, the line section located after the fault location, and the associated network stations, will remain de-energized until the fault is corrected. However, if it is a loop, step switching and testing can be performed in the same way from the opposite end of the 8400150 loop, eventually arriving from the opposite direction at the line section that is faulty, meaning that the network stations power can be supplied along the other part of the loop. The known method of reactivation is slow and cumbersome, since testing and switching takes place in.de; concerning network stations, which stations may be several kilometers apart.

The time during which the electricity consumers are without electricity will become long.

The object of the invention is to provide a method and device of the type mentioned in the preamble, with which a fully automatic restart of all network stations which are not connected to the damaged line section is possible and this damaged line section is shielded.

According to the invention, the method for this purpose is characterized in that one of the electric switching means, that after a loss of the control voltage it will first receive the control voltage after automatic closing, will be blocked in the closed position, while the other electric switching member opening in the event of a loss of control voltage within a predetermined period after this closing, in the open position 25 will be blocked against a further automatic operation.

The device according to the invention is characterized in that at a station with two alternative input lines, each of which is provided with an electric switching device which can be operated by a control voltage and which opens when the control voltage is lost, the electric switching elements are provided with a blocking unit which first blocks the electrical switch against opening, which first restores the control voltage, and blocks the other electrical switch in the open position when the control voltage is lost again.

The invention will be explained in more detail below with reference to the drawing, in which an exemplary embodiment is shown.

8400150 -3- ~

Pig. 1 schematically shows the basic function of the automatic load switching system? FIG. 2 schematically illustrates, in a simplified manner, the basic function of the load switch or interrupter switch for switching off the load; FIG. 3 is a diagram showing the structure of a control system for use in the present invention? 10 fig · 4 is a simplified representation of this diagram? and Fig. 5 schematically shows an application example of the device according to the invention.

In Fig. 1, connections 11 and 12 for the control voltage are shown at the top of the drawing. A charging resistor R serves to charge the capacitor C. T1 and T3 denote time delay trip relays, while T2 is a time delay trip relay. Furthermore, relays R1, R2 and R3 are shown, wherein the trigger relay R2 consists of a blocking relay and R3 is a trigger relay for preventing automatic unlocking, if a blocking has taken place automatically via the time relay T3. The sections indicated by a dotted line, i.e. the contact members, are shown in FIG.

Fig. 2 shows in a simplified manner the basic function of the load switch or interrupter switch for switching off the load, the voltage transformer of the control voltage source being designated UT and the interrupter switch LF. The control voltage can control the basic function in the following manner: a) when the control voltage drops without recovering within a predetermined period - compare the time relay T1 in FIG. 1 - the load switch LF opens.

b) when the control voltage recovers and remains present for a predetermined time - compare the time relay T2 of FIG. 1, the load switch LF closes.

84 CO 1 50 -4- P1 <% c) when the control voltage drops within a predetermined period after the load switch LF has been closed according to b) - compare the time relay T3 of fig. 1 - opens the load switch and is blocked against a further automatic operation. Regardless of changes in control voltage, the load switching means will therefore remain in the open position.

Fig. 3 schematically shows a switching element which can be operated by a control voltage in two different input lines to the same station.

Each input line is provided with such an electrical switching element, for example an interrupter switch for switching off the load. The control source is always common to both electrical switching members and will automatically be the one of the two power lines that are in position 2 or - in case both power lines are in position - the one of the power lines which are first under tension is put. The control voltage source causes the closing of the electrical switch member which has been opened and blocks the release circuit for opening the switch member in the input lines of the respective control source. Therefore, if the control voltage drops, only one of the two electrical switching members will open. If, after the electrical switch has been closed again, ie the control voltage has been restored, the control voltage drops again within a predetermined period, a switch will open again, namely the unblocked reverse electric switch, and according to the invention these are blocked in the open position so that it can no longer be operated automatically.

On the other hand, when both input lines are in position and one of the switching members is in the open position and is blocked from automatic interference, while the voltage for one input line drops without recovering within a predetermined period, then the blocking of the opened switch member are broken and brought to the closed position automatically. This removal of the lock can only take place if it is the result of a manual non-automatic switch-off action.

It can also be deduced from FIG. 3 that the control voltage source, namely the voltage transformer 5, supplies supply voltage for closing the electrical switching means, while at the same time charging a capacitor of such capacity that it can open released if the control voltage should drop. Therefore, no batteries or other control voltage independent resources are required.

Fig. 4 shows the device according to Fig. 3 in a simplified manner. The voltage transformers of the control voltage sources are indicated by spT1 and UT2, while M1 and M2 denote so-called motor units 15 with switches, which are surrounded by a dotted line in FIG.

According to the application example of Fig. 5, network stations A, B, C, D and E are arranged along a loop. The loop is connected to a power supply line 20 via switches S1 and S2 and an assumed error between network stations B and C is indicated by X.

When the error occurs, switches SI and S2 will be turned off and the entire loop SI-A-B-C-D-E-S2 will be de-energized. After a certain adjustable time without voltage has elapsed, one of the breaker switches A1-A2, B1-B2, C1-C2, D1-D2, E1-E2 opens in each loop-connected station, while the other switch remains in the closed position.

When the switch SI is turned on after a predetermined period of time, automatically or manually, one, AUT1, of the voltage transformers of the station will be activated. During the subsequent course of the operations, the two interrupter switches A1 and A2 will be controlled by this voltage source, since the voltage transformer U2 has not yet been energized. After a predetermined period, the one of the circuit breaker switches A1 or A2 opened by the loss of voltage will be brought into the closed position, while the control circuit for automatically opening the circuit breaker switch A1 will become 8400150-6. blocked by the operation of the blocking relay R2 (see fig. 1). From this moment on, the line section A-B will be turned on and at the same time the control voltage transformers AUT2 and BUT1 will receive voltage.

This does not affect the selection of the control source in station A in any way, since the voltage transformer AUT1 for AUT2 is energized and, as noted with reference to FIG. 3, that input line which is first energized has been brought.

In the station B the same process is repeated as in the station A and will subsequently cause the line section B-C to be switched on. As a result, the switch SI is automatically turned off, so that the entire section S1-X is de-energized. The loss of voltage results in the opening of the interrupter switches A2 and B2 and the blocking of the automatic control system of the latter switch against a further automatic influence in the manner as indicated above with regard to Fig. 1 under c). .

When the switch S1 is turned on for the second time, the voltage controlled operations in station A are started, whereby the interrupter switch A2 closes and the line section A-B will receive constant voltage. Since the voltage dropped 25 for the second time, the interrupter switch B1 in station B has remained in the closed position, while B2, as mentioned, is open and blocked.

The remainder of the loop S1-A-B-C-D-E-S2 is switched on from the opposite direction, ie from S2. The same sequence of operations described above now takes place at stations D, E and C. Successive automatic switch-on attempts eventually reach the line section with error X from the opposite direction. When the interrupter switch Cd is locked in the open position, all stations are energized again and the one is one. error erased line section B-C disabled.

The time required to automatically turn off a faulted line section and recover the voltage for the remaining sections is of course important. The location of the error relative to the entry points and the number of stations connected between these points is of course important here, as are the operating times chosen for the automatic means. If it is assumed that switches S1 and S2 automatically turn on again after 10 seconds and that the recovery time, that is, the time, must elapse after the switch is turned off automatically, so that the next switch-off will not be final, Is 15 s and the closing time of the interrupter switch, that is, the operating time of the actuators is 15 s, the resulting time in the most unfavorable fault position indicated in the example described is: 10 + 5 x 15 +10 + 4 x 15 = 155 s. The automatic process 15 therefore takes only 2-3 minutes.

The described method and device have the advantage that the parts required for the described operation, motor operating means and shunt switch-off magnets / blocking relays, are relatively simple and therefore require little maintenance. In addition, no special measuring or control lines are required between the stations or for a common control center, control rooms or the like. Furthermore, no separate resources for the automatic operation are required, but conventional voltage transformers can be used.

The invention is not limited to the above-described exemplary embodiment, which can be differentiated within the scope of the invention.

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Claims (4)

1. Method for automatically blocking an interrupter switch located near an error location for switching off the load, in particular at stations with two input lines, each input line being provided with an electrical switching element, for example an interrupter switch for switching off the load which opens when a control voltage drops for more than a predetermined period and closes when the recovery of the control voltage lasts longer than a predetermined period, characterized in that one of the electrical switching means which, after the control voltage will receive the control voltage first after automatic closing, will be locked in the closed position, while the other electrical switch of the station, which opens upon loss of the control voltage within a predetermined period after this closing, will open in the open position position will be blocked against a further automatic influence. Method according to claim 1, characterized in that at each station with two input lines, each having a breaker switch with a common control source, the one of the two input lines, which is in position, or, if both are in position 25, which input line, which is first energized after dropout and restoration of the control voltage, may effect closing the associated open interrupter switch and blocking a release circuit for opening this interrupter switch in the affected input line, while only the second interrupter switch automatically can. opening, and if the control voltage drops within a certain period of time after the closing time, the interrupter switch thus opened will be locked in the open position. 3. Device for applying the method as claimed in claim 1 or 2, in particular at stations with two input lines, each input line comprising an electrical switching element, for example an interrupter switch for switching off the load, 8400150 -9- "» this opens when a control voltage drops for more than a predetermined period and closes / when recovery of the control voltage takes longer than a predetermined period, characterized in that at a station with two alternative input lines, each of which is provided of an electric switch operable by a control voltage, which opens when the control voltage is lost, the electric switching means are provided with a blocking unit, which first blocks the electric switching means, which first receives the restored control voltage, from opening and the other electric switch in the open position locks at e and loss of control voltage again. 4. Device as claimed in claim 3, characterized in that a capacitor C is connected to the control voltage source and is charged by the control voltage in such a way that the electric switch members or interrupter switches can switch off the load in the event of loss of the control voltage. . if 8400150