DE477832C - Safety device for electrical multi-phase power transmission networks with a single-conductor cable as a replacement line - Google Patents

Description

Safety device for electrical multiphase power transmission networks with a single-core cable as a replacement line It is known in the case of an electrical Multi-phase power transmission system a single single-core cable as a reserve for to relocate the case that one phase of the multiphase system due to damage must be taken out of service. The reserve line can each have one Switch with any phase in place of the diseased line of the power source or the consumer network. will. One must now prevent that mistakenly several switches belonging to different phases are closed at the same time and as a result short circuits occur between the individual network phases.

According to the invention this is achieved in that a switching device is provided that responds in the event of a fault in one of the lines to be monitored and automatically disconnects the diseased line from the network and - the replacement line switches on in place of the sick line.

With reference to the embodiments shown in the accompanying drawing the invention is to be explained in more detail. In Fig. I is an embodiment the invention shown for one end of a three-phase line group. At the other The same circuit arrangement must of course be provided at the end of the lines.

44 are the busbars of the station to which the lines 6o, 61 and 62 are connected via disconnectors 8o, 8i and 82 and oil switches 64, 65 and 66. The oil switches can be switched on either manually or automatically. Each of them is equipped with a coil 85 which, when energized, triggers the switch assigned to it. Lines 9 i, 92 and 93, which lead to contacts 51, 52 and 53, are branched off from the network qq-. These contacts are controlled by a switching device 75 in such a way that, in the event of a fault in one of the lines 6o, 61 or 62, that contact 5i, 52 or 53, which is connected to the mains phase connected to the disturbed line, via the changeover switch 75 and the switch 67, which can be switched on by a coil 84, is connected to a replacement line 63. The changeover switch 75 consists of a contact lever So which is fastened to a rotatably mounted plate 58. A spring 55 acting on this endeavors to rotate the plate and with it the contact lever counterclockwise. However, this is prevented by an electromagnetic holding device which is excited as long as the lines 6o, 61 and 62 are in a proper state and which, in the excited state, holds the plate 58 in the position shown. Arranged on the plate 58 is a pair of contacts 94 which, in the closed state, close the circuit of the switch-on coil 84 of the switch 67.

The urine switch 75 cooperates with relays 25, 26 and 27, the are each assigned to one of the lines to be monitored. These relays are arranged so that when the relay coil is energized, its core has a stop for the contact lever 5o connected plate 58 forms and the contacts 94 closes.

The arrangement is such that the plate 58 is held up by one of the relays in such a position in which the contact lever 5o touches one of the contacts 51, 52 or 53. Which of the contacts 51, 52 or 53 this is, of course, depends on whether the relay 27 has responded. The relays 25, 26, 27 open the contacts 22, 23 and 24 in the energized state. These contacts control the excitation circuit of the holding device 56. The excitation circuits of the relays -95,: 26 and 27 are controlled by relays 34, 35 and 36. These relays are held in normally energized condition by springs in such a condition that they do not close either their upper or lower contacts. They are excited via a voltage converter 83. This consists of three single-phase voltage converters, each of which is connected to one of the lines 6o, 61 and 62. The primary windings of the transducers are connected in stars. The star point is grounded. The secondary windings of the transducers are connected to the excitation coils of the relays 34, 35 and 36. The relays are thus influenced by the voltages on lines 6o, 6 1 and 62 to earth. As soon as there are undervoltage against earth in the lines, the relays close their lower contacts; in the case of overvoltages, however, the upper contacts.

The mode of operation of the arrangement is as follows: First of all, the line group should be in proper operating condition. Here all switching elements take the position shown. It is now assumed that a ground fault occurs in line 6o. As a result, the voltage of the line 6o to earth disappears and that of the lines 61 and 62 increases. As a result, relay 34 closes its lower contacts and relays 35 and 36 close their upper contacts. As a result, the trip coil 85 of the oil switch 64 receives power, from the positive line of an auxiliary power source 41 via the upper contacts of the relays 36 and 35, the lower contacts of the relay 34, the line 98, the coil 85 and the line 96 back to the negative line of the power source 41. As a result, the switch 64 triggers and disconnects the diseased line 6o from the network 44. When the relays 34 35, 36 respond, the coil 25 also receives current, and its excitation circuit runs similar to that of the Coil 85 from the positive line via the upper contacts of the relays 36 and 35, the lower contacts of the relay 34, the line 98, the coil 25, the line 95 and via the line 96 back to the negative line opens its contacts 22. As a result, the circuit of the holding device 56, which previously started from the positive line via the line 97, the coil 56, the contacts 24, 23, 22, the line 95, the Le itation 96 and back to the negative line was closed, interrupted at the contacts 22. As a result, the holding device 56 lets go of the plate 58 so that it and with it the contact lever 5o can follow the course of the spring 55. As soon as the stop (94) of the plate 58 rests against the core of the relay 25, the plate 58 stops. In addition, the contacts 94 are closed by the pressure between the plate and the core. In this position of the plate, the contact lever 5o is in contact with the contact 5 i, ie it is connected via the line 9.1 to that network phase to which the disturbed line 6o was connected. The arrangement must be such that the contact lever 5o is connected to the controlled contact before the contacts 94 are closed. As soon as this is the case, the circuit of the switch-on coil 84 of the switch 67 is closed, namely from the positive line via the contacts 94, the coil 84 and the line 96 back to the negative line. The switch 67 switches on as a result, so that the replacement line 63 is connected to the mains instead of the switched-off line 6o. The switch 67 closes when switching on the auxiliary contacts, which the signal device 76, the z. B. off. a lamp can be connected to the power source 4i. The lamp 76 thus indicates when the switchover is properly completed.

As soon as the fault has been eliminated, the switch 67 is opened and the switch 6,4 closed again, so that the line 6o reconnected to the network and the line 63 is separated therefrom. Since now in the voltage converter 83 again a normater If there is a load condition, the relays 34 # 35, 36 return to their original position in which they do not close any of their contacts. The circuit is therefore back in its original operating state and is ready to replace a line again.

In some cases it is now desirable to make the arrangement in such a way that a specific line does not serve as a substitute line, but that each of the four lines 6o, 61, 62, 63 can be a substitute line. Such an arrangement is shown in Figure 2. In this, the same numbers denote the same as in Fig. I. Lines 6o, 61, 62 and 63 are connected to network 44 via switches 64, 65, 66 and 67 and via isolating switches 68, 69, 70 and 71. The switch disconnector has three positions according to the number of phases. A switch-on coil e and a switch-off coil a are provided on each of the switches 64 to 67. The switching arrangement also includes a changeover switch 59, which works together with the changeover device 75, and a changeover switch 20, which is connected to the voltage converter 83. The changeover switches can produce connections for four circuits according to the four lines 6o to 63. Finally, a changeover switch 49 is also provided, which is connected to the contact lever 5o. This changeover switch has four positions 45 to 48, corresponding to the four lines present.

The mode of operation of the arrangement is as follows. First, it is assumed that the line is in proper operating condition and the three lines 6o, 6i and 62 serve as feed lines, while line 63 forms the replacement line. In this case, the switch disconnectors 68 to 71 and the switches 64 to 67 are in the positions shown. The changeover switch 2o connects the terminals 13 and 17, the terminals 14 and 18, the terminals 15 and ig and finally the terminals 16 and 21 with each other. The terminals 17, 18 and ig are connected to the relays 34, 35, 36, while the terminals 16 and 21 close the circuit of a signal device 76, which indicates the changeover has taken place. The changeover switch 59 connects the clamping ends and 8, 2 and 11, 3 and io and 4 and g to one another. As can be seen from the drawing, these connections bring the opening coils of switches 64 to 66 under the influence of relays 34, 35 and 36 in a manner similar to that described in FIG. The changeover switch 4g is in such a position that the contact lever 50 is connected to the terminal 48 which is connected to the switch 67 of the line 63 which is currently used as a replacement line. It is now assumed that a ground fault occurs in the line 61. The relay 35 closes its lower contacts as a result of undervoltage, and the relays 34 and 36 close their upper contacts. This has the consequence that the opening coil a of the switch 65 receives power from the positive line of the power source 4i via the upper contacts of the relay 34, the upper contacts of the relay 36, the lower contacts of the relay 35, the terminals 3 and io of the switch 59, the coil a back via the line 96 to the negative line. The switch 65 triggers as a result and disconnects the line 6i from the network. Of course, the same thing happens at the other end of the leadership group. In addition to the coil a of the switch 65, the coil 26 receives current, in a manner similar to that of the coil d from the positive line via the upper contacts of the relay 34, the upper contacts of the relay 36, the lower contacts of the relay 35, the coil 26 via line 96 back to the negative line. The relay 26 responds as a result and opens its contacts 23. This interrupts the circuit of the coil 56 of the holding device. The contact lever 5o was raised in a similar manner as in the arrangement of Figure I - is described, the contact 52 a.. In addition, the contacts g4 are closed, so that the closing coil e of the switch 67 is excited from the positive line via the line 97, the contacts 94, the terminals i and 8. The switch 67 turns on as a result. Line 63, instead of line 61, is now connected to network 44 via switch 67, terminal 48 of changeover switch 49, changeover device 75, contact 52. The lamp 76 lights up to indicate that the changeover is complete.

The isolating switch 71 is now brought into connection with that phase to which the line 61 was connected. In addition, the changeover switches 49 and 59 are opened. Furthermore, with your changeover switch 2o, terminal 14 is connected to terminal 21 and terminal 16 to terminal 18. The lamp 76 goes out as a result, and the relays 34, 35 and 36 return to their rest position. After the cause of the fault in the line 61 has been eliminated, this can serve as a substitute line. For this purpose, terminals i and 6 and terminals 3 and 12 are connected to one another on changeover switch 59. Finally, the isolating switch 49 is placed on contact 46. The three-phase line group is now in operation with line 61 as a replacement line.

It can now happen that the earth fault as a result of direct earthing of a The zero point of a power transformer is a single-phase short circuit. In one such a case is not associated with an increase in voltage of the healthy phase to earth Security to be expected. If there is a possibility of such a short circuit, it is therefore advisable to provide the arrangement shown in Figure 3. In the case of this The arrangement shown, the relays 34, 35 and 36 are arranged so that they only respond in the event of undervoltage. They are in normal operating conditions in such a position that they close their upper contacts.

Claims (1)

PATENT CLAIMS: i. Safety device for electrical multi-phase power transmission networks with a single-conductor cable as a replacement line, characterized by a switching device provided with only a single contact lever, which responds depending on the faults in one of the network lines to be monitored and automatically connects the replacement line to the diseased phase. a. Safety device according to Claim i, characterized in that the only contact lever (5o) located between the replacement line and the network, in the event of a fault in one of the lines to be monitored, switches the replacement line to a switch position corresponding to the faulty phase by means of an (oil switch (67) on the faulty phase 3. Safety device according to claim i and 2, characterized in that the contact lever (5o) is in proper operating conditions without connection to the contacts (5i, 52, 53) of the mains phase, but in the event of a malfunction after the mains switch has been triggered on the disturbed line touches the contact of that phase to which the diseased line was connected 4. Safety device according to Claims 1 to 3, characterized in that a relay (25, 26, 27) is assigned to each network phase, which in the event of a fault in the phase corresponding to it responds and thereby brings the contact lever into the position that establishes its connection with the phase to which the damaged line is connected. 5. Safety device according to claim i to 4, characterized. that intermediate relays (34, 35, 36), which respond as a function of the operating state of the lines to be monitored, are arranged which control the relays (25, 26, 27). 6. Safety device according to claim i to 5, characterized in that further switching devices (4g, 59, 2o) are arranged, which make the individual switching elements so Umschaltbaff that 'not only the line originally intended as a replacement line, but each of the existing lines as Replacement line can serve.