DE527462C - Device for monitoring the operating status of an electrical energy distribution system from a central point equipped with a diagram of the energy distribution system - Google Patents

Description

Device for monitoring the operating status of an electrical Energy distribution system from a central one, with a diagram of the energy distribution system equipped place when operating electrical distribution systems makes itself more and more the need to set up a central monitoring point, from which the entire system is observed and operated as far as possible can be. For this purpose, measuring devices can be used to measure currents, voltages, powers, Display performance factors or the like of the individual routes of the system in the central office arrange. By observing these measuring devices, the surveillance officer is able to do so determine how the individual routes are loaded. With widely ramified and especially in the case of multiple meshed networks, however, the confusing multiplicity provides the displayed values do not provide a clear picture of the power distribution. For this According to the invention, the energy directions in the individual routes are the basis prevail in the distribution system, displayed in the monitoring station. The directions of energy provide very extensive information about the load distribution in intricate networks; they can also be easily illustrated in a replica of the entire system, as it is sometimes set up at central monitoring points. One can immediately Attach arrows next to the individual stretches of the replica to indicate the direction of energy show in real routes. Even if no such overview images Information about the size of the amounts of energy flowing in the real lines give, they have the advantage of great clarity. It's only second It matters whether the magnitude of the currents and voltages are also measured by telemetering devices etc. are displayed in the monitoring station.

The invention is of particular importance in the event that the plant a short circuit or a ground fault occurs. A short circuit, for example, affects the energy directions of all neighboring line routes, since in general the directions of energy are directed towards him from all sides. The replica of the line network therefore makes it possible to see the faulty route at a glance ascertain. If automatic line protection devices are installed, which Shut down the whole system or larger parts as soon as any of its routes a line fault occurs, it is advisable to take precautions, which those immediately after the failure occurs ruling energy facilities even then allow to recognize if the system is already in whole or in part is switched off. Means for performing this task are in the following Embodiments also given.

In Fig. I a device is shown, which is used to determine the direction to display the energy flowing in a route at a remote monitoring point. In this line, which is labeled L, a relay R is switched on, its Contact tongue a, depending on the direction of energy, a contact b or a contact c closes. These contacts are connected to poles B and G of a battery, the is tapped in the middle at 0. Guide from contact tongue a and point 0 Long-distance lines d and c in the monitoring point. Here is a magnet winding in switched into the long-distance lines d, e, depending on the direction of the current with which it is energized, sets a direction arrow P in one direction or the other. If no current flows through the coil, the inspection opening is either closed or the arrow assumes a vertical position. Depending on the direction of energy in the Line L is a signal current in either via contact b or contact c sent in one direction or the other via the solenoid. Are the distances that are to be bridged with lines d and e are very large, so it is advisable to the lines not directly with the display device, but with an intermediate relay to connect, which in turn only needs a local current to operate a direction indicator or a light signal closes.

If it is not important to display the energy directions during normal operation of the system, but if one only wants to draw a conclusion from the energy directions in the event of an overload or a line fault on the location of the increased energy requirement or the fault location, then one can be used Use the device as shown in Fig. A. The direction relay R1 is connected with its current coil to an auxiliary resistor W placed in the line L. Its contact tongue a is, however, connected to the long-distance line d via a contact K of an overcurrent relay = -M. The long-distance lines d and e lead to a direction-sensitive relay R2, which closes local signal circuits in the monitoring station. This relay receives no current as long as the overcurrent relay A1 does not respond during normal operation. But as soon as the distribution system is overloaded or a short circuit or earth fault has set in, the maximum relays M respond in all lines that are affected, and the corresponding relays R2 not only indicate the presence of the overcurrent, but also its direction . The supervising officer can see at a glance which parts of the line are overloaded and the direction in which the overcurrents are flowing, so that he can immediately give an account of the location of the increased energy consumption or the line fault.

In Fig. 3 a distribution system is shown with a central lying monitoring point H, in which a reduced image of the entire system is set up. The centers that supply the energy for the distribution system, are denoted by Z1 and Z2. The substations are designated with i to io, from which energy is taken. From the control centers Z1, Z2 and from all substations i to io lead to the monitoring point. H, through which the energy directions be transferred to the corresponding points of the simulation of the network, and only in the event that the normal line currents are exceeded. Of the Reason for the occurrence of overcurrent may be, for example, that with F between the substations 7 and 8 a short circuit has arisen. The direction pointer at the replica of the network, as shown in the drawing Is indicated by arrows. The supervising officer sees without difficulty that the all energy is directed to the line between the substations 7 and 8 is, and can take the necessary measures. However, a short circuit is not allowed remain in place for too long so that the power generators and lines are not endangered will. For this reason, the centers Z., Z2 by overcurrent switches Ml and M2 protected. A few seconds after the short circuit occurs, these switch the Energy. This shutdown may happen so quickly that the surveillance officer has not had time to identify the point of failure. For this reason is in accordance with the invention a device is provided in the event of a short circuit, the direction pointer hold firmly until they are inserted into theirs by hand or by any other device Zero position can be reset.

A device serving this purpose is shown in Fig. Q. shown. In the illustrated embodiment, it is also assumed that the monitoring station communicates with the individual substations through remote control systems, the they allow all necessary control movements via just two lines to be carried out in a substation from the monitoring point: The remote control devices have a contact arm i i in the monitoring system and a contact arm 12 in the substation. Both run over a contact disk 13 and 14 so uniformly that that they touch the corresponding contacts of these two discs at the same time. The individual contacts of the discs 13 and 14 are with the devices to be controlled connected or with relays that open and close signal currents between the two points. This is in the line L_ of the distribution network leading through the substation Direction relay R1 and the overcurrent relay M switched on. The direction relay controls a contact tongue 15 which, depending on the direction of the current, has a contact 16 or a contact 17 closes. These contacts are with your positive and negative Pole of a power source 18 connected. The contact tongue 15 is through a line i9 connected to a contact tongue 2o of the overcurrent relay M. This closes when Overcurrent in the line L flows, a contact 21, which is through a line 22 with a contact 23 of the contact disk 14 is connected. The surrounding contact arms i i and 12 are connected to one another by a trunk line 24. If the revolving contact arm 12 touches the contact 23, the revolving contact arm touches i i the contact 25 of the contact disk 13. The contact 25 is one pole with one polarized relay 26 connected, the other pole of which via a trunk line 27 to Center 0 of the power source 16 leads. The polarized relay 26 closes depending on the direction of the exciting current through a contact 28 or a contact 29 a direction signal 30 or a direction signal 31 in the circuit of a battery 32 is switched on.

During normal operation, the polarized relay 26 remains de-energized because the excitation circuit is always interrupted by contact 21. But overcurrent occurs on, the overcurrent magnet M closes contact 21. Assuming that the Direction relay R1 puts its contact tongue 15 on contact 16, then the following comes Circuit established: From the positive pole of the power source 18 via the contact 16, the Contact tongue 15, connecting line i9, contact tongue 2o, contact 21, line 22, Contact 23, contact arm 12, trunk line 24, contact arm i i, contact 25, polarized Relay 26 and through the trunk line 27 back to the zero point of the power source 18. The polarized relay 26 consequently closes its contact 28, and the direction pointer 30 lights up.

However, this lighting up would pass quickly, if only for that reason, because the rotating contact arms i i and 12 interrupt the signal flow again immediately. In addition, it must be expected that the safety devices built into the system either switch off the entire system or the overloaded part. Hence are facilities provided to the position of the contact tongue 15 of the direction relay Rl and the contact tongue To hold 2o of the overcurrent relay M at least until the contact arms i i and 12 have reached contacts 23 and 25. The contact tongue is used for this purpose 15 equipped with a magnet armature 33, which is held by the holding magnet 34, but cannot be attracted. The contact tongue 2o of the overcurrent relay is also M is provided with a magnet armature 35 which is held in place by a holding magnet 36 will. Both holding magnets 34 and 36 are only excited when the overcurrent magnet M a contact 21 and also the direction relay R1 one of its contacts 16 or 17 has closed. The excitation current then flows from the positive or negative Pole of the power source 18 via the contact 16 or 17, the contact tongue 15, connecting line i g, contact tongue 2o, contact 21, excitation winding of the holding magnet 36, excitation winding of the holding magnet 34, via a heating coil 37 and via a contact 38 to zero point 0 of the power source 18. The heating coil 37 is around a bimetal rod 39 laid. As soon as this is heated, it bends and opens the contact 38. The heating coil 37 is dimensioned so that the circumferential contact arms i i and 12 in any case, the contacts 23 and 25 have reached before the excitation current of the holding magnets 34 and 36 is interrupted again by the contact 38. Will the excitation current again interrupted, the contact tongue 2o goes back to its rest position, at least under the prerequisite that the overcurrent has disappeared in the meantime. The contact tongue 15 can adjust to the new direction of energy that may have arisen or, if so the line has become de-energized, also return to the central position.

The polarized relay 26 in the monitoring station is also included a holding magnet 40 is provided. This holds the contact tongue 41 in the once occupied Fixed position as soon as its field winding 42 via contact 28 or 29 from the battery 32 received electricity. The excitation current can if the supervising Officials finished the reading, canceled again by a break contact 43 be, whereupon the polarized relay 26 goes back to its rest position.

Claims (2)

PATENT CLAIMS: which existed immediately prior to shutdown. 3. Device according to claim i, characterized in that automatic devices (M) for remote display of the energy directions are only put into action when the electrical quantities of the distribution system (i to io or L) exceed predetermined limits. 4. Device according to claim 3, in which the signal currents for remote display of the energy directions are guided via two contact arms (11, 12) which close the individual contacts in a row of contacts at the same time, characterized in that the energy direction relays (R,) are in their contact position for so long be kept locked that the contact arms (ii, 12) have sufficient time in each case to close the signal currents for remote display. i. Device for monitoring the operating status of an electrical energy distribution system from a central point equipped with a diagram of the energy distribution system, characterized in that the respective energy directions that prevail in the individual sections of the energy distribution system are automatically displayed by marking devices in the diagram. 2. Device according to claim i, characterized by Hblteeinrichtungen (34, 36, 40), which in the event that part of the system is switched off, the display hold on to the direction of energy