DE495892C - Device for automatic reinsertion of automatic switches - Google Patents

Description

Device for automatic reinsertion of automatic switches Um In electrical distribution systems, not the entire system in the event of faults in the network To have to de-energize, the system is divided into individual Tuil: routes, so that the diseased route can be switched off without the other routes in To draw pity. It is often required that the disconnected line is automatically switched on again when the error has been rectified and there are quite a few suggestions for automatic reinsertion of the switch, the separates the sick line from the healthy one. With direct current systems, for example for railway purposes, has inan especially of resistance measuring devices Made use to monitor the resistance of the disturbed route and the re-engagement of the switch if the resistance is restored after the malfunction has been rectified has grown to a certain size.

The invention relates to such reloading devices of circuit breakers between adjacent DC line sections and consists therein "d.aß, d .e resistance measuring device in the event of a fault via rectifier is switched on. By having two rectifiers connected against one another the two adjacent line sections are connected, the measuring device be energized regardless of the location of the fault in the system.

In Fig. I an embodiment of the invention is shown at the one N # '' heatstone bridge circuit for measuring the resistance of the faulty now is used. Fig. 2 and 3 show two circuit diagrams according to the arrangement according to Fig. i, which result depending on the location of the disturbance.

io and ii are two sections of a DC circuit that run through an automatic switch 12 are connected. The return line is denoted by 13. In series with the circuit breaker 12 is the overcurrent coil i9.

The main switch i2. Is with a closing coil 14. and two auxiliary switches 15 and 16 provided. When switch 12 is open, the I-Elfs switch 15u is closed and the auxiliary switch 16 is open. The closing coil 1q. holds switch 12 at normal operation. closed. It lies in a circuit - that of the line section io via one, part of the resistor 17, via one controlled by the overcurrent coil ig Switch 18, the coil i. # L, the auxiliary switch 16 and a supply resistor: 2o leads to return line 13.

The resistor 17 .is connected to the line sections io and ii via the contacts 22 of a relay 21. The two resistors 28 and 29 in series, the load resistance W between line io and 13 or line ii and 13 and the resistor 17 form the four branches of a Wheatstone bridge, as clearly shown in Figures 2 and 3 The four corner points of the bridge are labeled A, B, C, D.

According to the invention, two par rectifiers 26, 27 and 30, 31 (for example copper oxide glasses) are connected to lines io and ii. The rectifiers of each pair are connected to one another so that they prevent the flow of current between the line sections io and ii. The rectifiers 26 and 27 permit the flow of current from the line sections io or ii via point 40, the auxiliary switch 15 to the coil or relay 2i and from there via the signals 34, 35 of a control relay 32 to line 13. The rectifiers 30 and 31 form on the other hand, the way back to the line sections io or 1 i for a circuit that leads from point B via the movable coil 37 (of the control relay 32 to point 41).

From the relay 2i four contacts 22 to 25 are stowed, of which, when the coil 2i is de-energized, the contacts 22, 23, 25 are open and the contacts 24 are closed. The contacts 22 are, as already described, in series with the Resistance: 17, while the contacts 23 are in the circuit of the closing coil 14. The contacts 24 close and interrupt the circuit of the movable coil 37 boring control relay 32. Through the contacts 25 (the circuit of the relay coil 21 independent of Aden B. Wegunbnen the contact member 34 of the control relay 32 closed held.

The control relay 32 consists of a magnet which is constantly excited by means of the coil 33. A permanent magnet can also be used in place of the electromagnet. The movable coil 37 of the control relay carries a contact arm 34 which is conductively connected to the line 13 via the tension spring 38. The contact arm, which is drawn in a central position for the sake of clarity, comes into play when the movable coil is noisy or has little current, by pulling the spring 38 with the lower counter contact 36. If, on the other hand, sufficient current flows in the coil 37, the contact arm 34 is connected to (the upper mating contact 35.

The device described works in the following way: If in the Both line sections 1o and i i normal states prevail, .is wire switch 12 closed. Its closing coil 14- is excited because it is in a circuit from line io via resistor @ i7, contact 18, coil 14, Hslfsscbalter 16 and resistor 2o leads to line 13. Since the switch 15 is open, so rist the coil of the relay 21 is de-energized. Also flows in the winding 37 of the control relay 32 no current because there is the same potential at their two poles.

If an overload or short circuit occurs in line section i i, this is how the overcurrent relay ig pulls its core. and opens the contacts i8. Through this the circuit of the closing coil 14 is opened and the switch 12 is triggered, so that the faulty line section ii is separated from section io. Of the Section io can therefore not feed the error in section i i.

When the switch 12 is opened, the auxiliary switch 15 is closed and so the resistor 28 and the coil of the relay 2i are connected to the point 40 between the rectifiers 26 and 27. These rectifiers are connected in such a way that current can flow from each line section to .dem point 4o. Since section ii is disconnected from its current source when switch 12 is open, its voltage is essentially zero, and current only flows from section io via rectifier 26 to resistor 28 and to Rellaissptile 2i.

As long as the tension of section io is higher than that of this section i i, section io supplies current via A to the rectifier 26, the control circuits (Section 2), but if! the tension of section ii that of the section io exceeds io, current flows from section i i through rectifier 27 the control circuits (Fig.3). The valve action of the equal forces thus becomes it exploited to select from several power sources the one to feed a circuit, which has the higher tension.

If the voltage .in io is higher than that in i i, then. electricity flows out the line section io via the rectifier26, point 40, the auxiliary switch 15, the resistor 28 and through the movable coil 37 of the relay 32 and the contacts 24 this relay 21 to the return line. The contact arm 34 on the movable coil 37, which was previously pulled to the rear mating contact 36, now sets against the upper contact 35. This causes -the circuit -the coil of the relay 21 (from io over 26, 40, 15, 21, 35, 34, 38 after 13) closed, it attracts its core, closes its contacts 22, 23, 25 and opens the contact 43. The contact 22 connects the resistor 17 with the section i i. By closing the contacts 23 is a Circuit for the Schfeßspule 14 of the switch 12 prepared. When opening: the contacts 24 becomes the circuit of the movable contacts 25 : serve to close a self-retaining circuit of the relay coil 2i, see above that this coil is completely independent of the movements of the contact arm 34 of the control relay 32 between points 40 and 13 remains switched on.

The by the resistors 17, 28, 29 and the load resistance W formed Wheatstone bridge circuit is electricity from the line section io supplied via the rectifier 26. The coil 37 of this control relay 32 is on the one hand to point B between the resistors 28 and 29 and on the other hand via the rectifier 31 connected to the line section il (point D). If an error occurs between lines 11 and 13 up, the resistor W forms between these lines the unknown resistance to be determined by the circuit.

By setting, for example, ides Resistance! Des 29, one asked it in hand to achieve that -the control relay 32 a contact closure between the contact arm 34 and the lower mating contact 36 brings about as soon as the resistance W between the lines i i and 13 again reached a certain value.

Closing contacts 34 and 36 creates a circuit from the section io (point A) over the left half of the resistor 17, contact 18, closing coil 14, contact 23 of the relay 21, contacts 36 and 34 and via the pulling fender 38 according to Line 13, closed. The coil 14 attracts its core and closes the main switch 12. The auxiliary switch 15 is opened, whereby (read Pel @ aiis 2i currentless will. The auxiliary switch 16, however, is closed and keeps the circuit of the Closing coil 14 closed from io to 17, 18, 14, 16, 2o to 13. Well they are Line sections io and i i connected to one another again by the main switch 12.

If an error occurs, not as described between lines i i and 13, but between lines io and 13, the same circuits occur as described. The resistance to be measured, W is now between line io and 13 (Aibh. 3). The bridge circuit is fed via the rectifier 27 from the line section ii. If the resistance W rises again to a certain value, the control relay 3: 2 closes the contacts 34 and 36, and the closing coil 14 causes the main switch 12 to be switched on.

In Fig. 4 is an arrangement for reinserting the main switch 12, which is similar to that of Fig. I. Instead of the Wheatstone bridge circuit a different resistance measure is chosen. To the Luitu: agen io and i The rectifiers 26 and 27 connected in series are connected. Of the Main switch 12 is connected to auxiliary switches 16, 151, 152, the core; des Relay 21 with contacts 22 to 25. The relay 21 is as in the arrangement according to Fig. I from lines io or ii via point 4o- between the rectifiers fed when the auxiliary switch 151 is closed. The relay is controlled 2i of the tax rate or resistance measurement triangle 32. This is impressive on one level Horizontal bar-like arm 34 on which two relay coils 37 and 38 act. The arm 34 is conductively connected to line 13. Its ends can be with the mating contacts 35 and 36 come into contact. By means of the auxiliary switch 151, the Reuaiss coil 37 across the series resistor, 5 i between point 40 and the Laitwn: g 13 be switched. The relay coil 38 is via the auxiliary switch 152 and ballast resistor 52 on the one hand to the center of the resistor 17, on the other hand to line 13 connected.

During normal operation, the switch 12 and the overcurrent relay are closed ig de-energized. The relay 21 is de-energized, and the control relay 32 is m a position in which the contact arm 34 know the two mating contacts 35 or 36 .touched. The closing coil 14 is energized (circuit io, 17, i8, 114, 16, 2o, 13) and keep the main switch 12 closed.

In the event of an overload, for example, the line section i i opens the Überstromrehis i9 the contact 18. The Sch1ießspu ile 14 is de-energized, and the Main switch 12 trips. The auxiliary switch 151 closes and switches the Relay coil 37 between point 40 and line 13. It flows, so .a current from line io to relay coil 37, this responds and lies against contact arm 34 against contact 35. This switches on the relay coil 21 (circuit OK, 26, 40, 151, 21, 35, 34, 13) and closes their contacts 22 to 25. The resistor 17 is now switched via the contacts 22 between the lines io and i i.

By closing the contacts 25, the circuit of the closing coil 14 of the main switch, which is closed when the contact arm 34 den: 36 touched. Through the contacts 24 the circuit of the coil 38 of the control relay is 32 closed.

It is essential for the resistance measuring circuit that the current in Edier relay coil 38 is directly proportional to the voltage drop between the lines i i and 13 increased by the voltage drop of the right-hand part of resistance 17 is. The current in 38 is a measure of the voltage between the lines i i and 13. In contrast, the current in the relay coil 37 is proportional the voltage between line io and 1.3.

In the event of a high overload, this is the voltage between line i i and 13 very small., the relay coil 38 is excited much less than the relay coil. 37. If the load resistance W increases (Fig. 5) and @ with it the voltage between the Lines i i and 13, the excitation of the relay coil 38 increases. With further If the voltage increases between i i and 13, the tensile force of the coil 38 outweighs that the coil 37, and the contact arm 34. is lifted from its mating contact `35. The circuit of the relay coil 21 is not affected because it over the contacts 25. remains closed.

As soon as the tensile force of the coil 38 increases, the contacts 34 and 36 are closed, the circuit of the closing coil 14 is closed. Düese responds and puts the main switch 12 back on. At the same time, the Auxiliary switches 151 and 152 open and thus the two coils of the control relay 32 switched off.

In: Figs. 5 and 6 are essential for resistance measurement Schaltangen shown when the fault between the lines, i i and 13 or occurs between io and 13. The operation of both circuits is natural quite the same. In both cases, the control relay switches the closing coil 14 of the switch i2 on again when the resistance W has grown to a certain level is.

Claims (7)

PATENT CLAIMS: i. Device for automatic reinsertion of circuit breakers between adjacent DC line sections by means of Resistance measuring device, characterized in that the measuring device upon entry a fault in a line is switched on via rectifier and when it re-enters normal conditions in the disturbed route brings about the re-engagement of the switch. 2. Device according to claim i, characterized in that a pair of mutually connected Rectifiers are connected to the two adjacent line sections. 3. Device according to claim i, characterized in that, the resistance-smeßeinrich, device in the event of a malfunction, it is cleaved to the tensioning of the undisturbed route. q .. Facility Mach claim i, characterized in that -the energy for reinsertion, des Switch is taken from the undisturbed route. 5. Device according to claim, 3, characterized by @ d @ ate the line to take the energy for reinsertion of the switch is connected to the middle, a resistor (17) whose free Ends are connected to the two line sections. 6. Device according to claim i, eda-. characterized by: diaß to measure this resistance of the disturbed, Line route a Wheatstone bridge circuit used wind, in, whose diagonal a control relay is located, which when the normal state returns to the disturbed Stretch the closing coil of the switch in the other diagonal of the bridge switches on. 7. Device according to claim i, characterized in that the resistance measuring device a relay with two counteracting coils, one of which is connected to the Voltage of the undisturbed line and their other to the voltage of the disturbed Route is connected.