DE955070C - Protection circuit for electrical consumer systems, especially lighting systems in underground operations - Google Patents

Description

Protection circuit for electrical consumer systems, in particular Lighting systems in underground operations Protective circuits are proposed have been, in which the consumer feed lines are adjacent to a protective and a Supervision manager or a corresponding system is assigned so that the line both to external errors, d. h_ such between the supervisor and the Protective conductor or on these conductors, and furthermore for internal faults, d. H. such between a main conductor or feeder of the consumer and the protective and Supervision ladder system can be monitored. For monitoring internal faults, d. H. a gap between a consumer feeder and, the protective conductor or because supervisor, it has been suggested, a supervisory device to use, which is between a main conductor and a suitable measuring voltage source is switched on, this voltage source if necessary. at the same time for other functions can be used, namely for feeding the protection and Monitoring: conductor system for the purpose of monitoring for external faults. Such Arrangement, however, has the peculiarity that it is between the consumer feed lines switched on consumers, z. B. Incandescent lamps., As a necessary current bridge system bills. So if all consumers are removed, there is none necessary current bridge. Another similar case in which the Arrangement no longer proves very effective is that of consumers or consumers have a very high internal resistance. In this case it results one Imbalance in the supply of the monitoring device, namely in the case of a internal fault in the form of a termination of a main conductor with the protective and supervision ladder system only a slight resistance by the line system in the monitoring circuit is switched on, while in the event of an internal fault with the other main conductor in the consumer high monitoring circuit Internal resistance is switched on, so that a supply of the monitoring device only takes place with a correspondingly reduced energy. It would therefore be necessary the monitoring device for the proper control of these cases explained last to be dimensioned for a very wide response range, which is not practical.

To remedy these deficiencies, the task is all main conductors directly with the Monitoring device in electrical. Keep in touch.

According to the invention, this object is achieved in that the monitoring device for internal faults is connected to each of the feed conductors via a resistor at the beginning of the consumer system. In the case of two feed lines for feeding the consumer, this resistance is preferably in the manner of an optionally adjustable one. Voltage divider used. If there is a three-phase system, an analogous solution is obtained by creating an artificial star point between the three feed lines via appropriate resistors, which can be ohmic or inductive in character. If an internal error now occurs, a direct circuit is created via the corresponding main conductor and the voltage divider for the monitoring device. In such an arrangement, where only one. General electrical resistance is used of ohmic or impedance character, is when a relay responsive to direct current is used in the monitoring device, whereby care should be taken at the same time to ensure that the superimposed alternating current in the event of an internal fault exceeds a certain limit value, e.g. B. with a view to avoiding the formation of ignitable sparks, does not exceed a protective resistance in series with your monitoring relay, but at the same time a correspondingly high one. DC voltage source required for monitoring. If the path is taken that the responsive to direct current monitoring device is bypassed for the alternating current, z. B. by a calming capacitor, the alternating current appearing in this way has such a high value that it turns into ignitable sparks. This can give rise to, if the capacitor is not dimensioned correspondingly small. On the other hand, as a diversion capacitor, the capacitor must have a certain minimum size, because otherwise the relay will work unsteadily. According to the invention, however, these relationships can be mastered by using rectifiers, preferably in the form of dry rectifiers, as bridging or voltage divider resistors for connecting the monitoring device for internal faults to the main conductor. In this way it is achieved that in the event of an internal error in any case about the per se, for reasons. In order to achieve a high level of sensitivity, a monitoring device working with direct current only flows direct current and a rectified alternating current. In the event of an internal fault that occurs, the load feeder system with the rectified voltage derived from it and having a relatively high value as the driving voltage for the monitoring device is the first determining factor; while in the monitoring device per se it is expedient to work with a small measuring voltage. In order to control these voltage conditions accordingly, the device according to the invention is designed in such a way that when the monitoring device responds to an internal fault, a protective resistor initially provided in the line of the rectified AC voltage feeding the monitoring device is switched off and the low-voltage power source is then switched on immediately for the purpose of fault location, the monitoring system is put in place. This location was carried out according to an earlier proposal in such a way that at predetermined separation points, which are specified in the feeder system. or are specially provided, calculated from the feed side of the system, which could be separated from the following parts of the line. To. Successful disconnection of the part of the line that gave rise to the error turns out to be. the part of the valley line that is to be located after the feed side is free of errors, and thus a positional location of the error is achieved. For this purpose, the device was designed in such a way that when the consumer lines are switched off in the event of a line fault, the line still remains connected to the monitoring device after the main supply has been switched off. With the separation of the faulty. Line part by the locating process then the monitoring device releases the line system again for the proper feeding of the non-faulty line part, calculated from the feed side.

Illustrate an example embodiment for practicing the invention the figures of the drawing.

In Fig. R, r and 2 denote the feeder of the system, which over a transformer 3 and the contactor 6 are connected to the consumer feed lines 4 and 5 can be. Between these feed lines are as consumers, for example Light sources 7 switched on. 8 or 9 form a monitoring conductor or protective conductor, the consumer lines 4 and 5 in the line body adjacent assigned. There are control switches in the monitoring ladder for fault location - i i is a differential relay. Both windings of this relay are once connected to the voltage source 12: the other end of the line. Winding is via the resistor 14 to the. Connected at the beginning of the protective conductor, the other End of the second winding via a resistor 15 to the end of the protective conductor 9. 13 denotes a switch for switching on the supply voltage source 12. It can be seen that if there is an external fault in the line system 8, 9 according to the lightning bolt I applied in the form of a line between the supervisor 8 and your protective conductor 9 or in the event of an error according to the II and III designated interruptions occurs, the monitoring relay i i through the resulting Urisymmetry of the supply to its windings. an addressing of his switching organ 16 brings about by this is switched either to the contact 16a or 16b. As a result, the Spv: le of the relay 17 is short-circuited, which is of the Voltage source 12 is fed via the switching element 2o of the relay 21 and the resistor 18 is, so that the switching element 17 "opens the circuit of the contactor coil 6" and that Contactor disconnects feed lines 4 and 5. The supply of the relay. 21, which for monitoring internal faults, is done for the purposes of the present Invention by connecting the relay to the. Voltage divider resistor 22 is connected. So there is always an immediate, independent of the consumer power sources Connection of this monitoring relay to each of the main feed lines to be monitored before. The mode of operation of the protective circuit in the event of an emerging. inner error., z. B. according to the entered lightning arrow IV, is the following, whereby initially under.tellt is that the contactor 6 is switched on, what then with fed lines i and 2 the switching element 17a must also be in the left switching position. By the resulting error is closed by the line 5 via the circuit Error IV, furthermore preferably via protective resistor 15, protective conductor 9, the closed switch 13, the voltage source 12, whose tapping point 12 " the winding of the relay 21, the voltage divider resistor 22, back to the main conductor 5. As a result, the relay 2i responds, its switching element 2o opens, the circuit. the relay 17 .is interrupted, its switching element 17 "opens the circuit of the Contactor coil 6a, and the contactor falls out. Even after the consumer feed lines have been switched off the monitoring relay 21 is still connected to the DC voltage source and to each of the Feeder 4 and 5. You could now use the present inner. Error z. B. locate, by little by little pieces of the consumer line, counting from its end, separates. As soon as the faulty line section is switched off, the supply of the relay 21 interrupted, its switching element 2o closes the circuit for the relay 17, and this closes the circuit for via its switching element 17 " the main contactor 6, so that: ß the consumer feed lines 4, 5 switched on again and, in the case of a lighting system, the lamps immediately when they light up indicate the elimination of the error. One operator only needs the route to step from its end and the corresponding scraping measures by cutting off of the line sections without a second operator for this work to have to avail.

In fing. 2 shows a part of the circuit of FIG. I, so far it for the understanding of a further development according to the invention of a circuit arrangement according to Fig. i is required. In this circuit arrangement according to Figure 2 is the Voltage divider resistor 22 replaced by two equals 23a and 23b opposite one another Forward direction. The contactor 6 "is in this case with an additional auxiliary switching element 24 provided which, depending on its switching position, the upper contacts 25 or the lower contacts 26 bridged. If the switching element is in the upper switching position, so just becomes a through line. created between the connection to dien Rectifiers 23a and 23b and the winding of the relay 21, while in a bridging of the lower contacts 26, a protective resistor 27 is switched on in this cable run is. It can be seen without further ado that if there is an internal error and fed system i, 2 and closed contactor 6 initially the rectified Alternating current flows through the monitoring relay 2i for internal faults and this makes you respond. Here, the protective resistor 27 acts as a corresponding current limiting device in the operating state in which the rectified voltage is used as the driving voltage The voltage of the consumer system is effective. After - switching off the consumer feed lines when the contactor 6 drops out, the switching bridge 24 is connected to the contacts 25 and in the monitoring circuit, the voltage source 12 is now effective, without having to overcome a protective resistance. As a precaution, it is pointed out that that with the rectifiers 23a and 23b in series connection if necessary suitable Protective resistors can be used so that in the event of a fault on a the rectifier systems not the other rectifier system or the monitoring system Can suffer damage. The power source, which in the exemplary embodiment is in the form of a Battery 12 is shown, can of course also by a rectifier arrangement formed via a transformer from the power lines in front of the contactor 6 is fed for the consumer lines.

Claims (1)

PATENT CLAIMS: i. Protective circuit for consumer systems, in particular lighting systems for underground operations, with the consumer feed lines being assigned a protective and monitoring conductor system which, in the event of an internal fault between, a feed conductor and the protective or monitoring conductor via a monitoring device located on the consumer system with an auxiliary power source at the beginning of the line switches off the supply of the system, characterized in that the monitoring device for internal faults via one each. Resistance at the beginning of the consumer system is connected to each of the feed conductors. z. Protection circuit according to. Claim i, characterized in that the monitoring device is connected to bridging resistors between the feed conductors. 3. Protection circuit according to claim i and z, characterized in that, in the case of a multi-phase system, the monitoring device is connected to an artificial zero point formed by resistors. q .. Protection circuit according to claim i or one of the following, characterized in that rectifiers are used as resistors in a circuit with forward direction for the DC measuring voltage. 5. Protection circuit according to. Claim q., Characterized in that protective resistors are provided in series with the rectifiers. 6. Protection circuit according to claim i or one of the following, characterized in that when an internal one arises. Error the monitoring device is actuated by the rectified AC voltage of the feed line system via a protective resistor to limit the current and, when the main feed lines are switched off, by bridging the protective resistor, it is switched directly to a DC voltage source with a low voltage value. Considered publications: German Patent Specifications Nos. Z87 609, 836 379.