DE615688C - Device for determining the degree of earth fault compensation in high voltage networks - Google Patents

Description

GERMAN EMPIRE

ISSUED ON JULY 10, 1935

REICH PATENT OFFICE

PATENT LETTERING

CLASS 21c GROUP

General Electricity Society in Berlin *)

Patented in the German Empire on January 12, 1929

When businesses of high voltage networks, the ground fault current obligations by Löscheinrich- ^1, z. B. earth fault coils, is compensated, there is a need to have clarity at all times as to whether the network is in the state of the best possible compensation or, if not, how far it is from it. The extinguishing current, ie the current to be supplied by extinguishing devices, which must be added to the current of the extinguishing devices that have already been switched on, so that full compensation occurs, can be used as a quantitative measure of the prevailing degree of compensation.

This task is not new and proposals for solving it are already known. According to the known solutions, a measurement is always carried out on the high-voltage network itself. which arise under the influence of an additional voltage introduced for this purpose and are dependent on the prevailing compensation state, for feeding a directly indicating Serve instrument. Such devices are generally quite useful.

In networks with a very large earth fault current and a highly variable switching state, for example in extra-high voltage networks, however, there are difficulties insofar as the for Generating the auxiliary voltage required equipment is relatively large and expensive and, moreover, the compensation status of the network not under all circumstances reveal. During an earth fault itself, the known ones fail Measuring devices, and it can happen that changes in the switching status due to an earth fault occur not immediately noticed in the network, so that the compensation state was known before the disturbance and the extinguishing current could be set accordingly, but that after the malfunction has expired, but still with an existing earth fault, the compensation state is unknown and possibly is not allowed. Since one is used to operating in networks with earth fault compensation for hours in the event of an earth fault, means this uncertainty, especially with the networks mentioned at the beginning high earth leakage current, a hazard to operation.

In order to be able to check the compensation conditions in the network even in the event of disturbances, a network model has already been provided in which, depending on the switched-on power supply unit, correspondingly switched-on, true-to-resistance images are arranged. The capacities of the switched-on power supply units to earth can then be determined from this, and the values to be switched on from these values.

*) The patentsitcher stated as the inventor:

Dr. Hans Piloty in Berlin-Wilmersdorf.

Calculate extinguishing coils or parts of the extinguishing coil. Apart from the required This method has the further disadvantage of arithmetic operations that it is switched on and settings of the compensation coils are required. A control of how far the compensation now available does not meet the requirements of the network. To now automatically ίο monitor the vote and furthermore without any setting in the network models manually the ones actually available at any time To be able to check the degree of compensation, according to the invention, in a measuring or display instrument, the difference from a the measured variable corresponding to the total earth fault currents of the switched-on power supply units on the one hand and on the one hand the total extinguishing currents of the activated extinguishing devices corresponding measured variable on the other hand brought into effect. The individual measurands are each generated by a network simulation, each of which is controlled by relays that depend on the position of Auxiliary contacts on the display organs of a reproducing the switching state of the network Are dependent on the circuit diagram. By arranging a second model for extraction the extinguishing currents and the comparison of the measurands that the two models deliver automatically the actual compensation ratios after each setting of the Extinguishing device can be determined without further ado. By controlling the two Resistance models, caused by the display element of one of the switching status of the network reproducing circuit diagram, every certainty is automatically achieved that also the preconditions on which the measurements are based regarding the switched on Power supply units and the settings made for the extinguishing coils are correct. Accordingly, it takes place without any external assistance with the greatest certainty the most precise determination of the respective tuning ratios in Network.

The invention also has over a known device in which on a Ammeter a second scale is arranged, which is the control setting of a Extinguishing device indicates various advantages. In the case of the known device, it will only enables the earth fault current to be read at a certain level can determine which setting corresponds to an extinguishing coil of this size. This facility has the first disadvantage compared to the invention that it is only in use a single extinguishing device is useful: furthermore, that it does not reveal oil) the earth fault coil has really taken on the required setting. Especially when the installation location of the earth fault coil and the monitoring device do not coincide, there is no possibility of determine whether the voting conditions are correct. The current used to feed the ammeter is used in the known device is also supplied by a true-to-resistance image of the network. The image itself, however, does not show the switching state of the network as a function of the display element Circuit diagram controlled. It is therefore necessary in the known device that Set the network image yourself in order to get the correct current for the monitoring instrument in the first place to obtain. This laborious work, which can easily lead to incorrect settings, is also avoided in the invention.

The device forms the basis of the positions of the display elements of the network image according to the invention measured variables, each of which is a line section or corresponds to a tap of an extinguishing device. All measured quantities are the same physical nature, for example pressures, electrical voltages or currents. The simulations that generate the measured quantities are with one another and with one Measuring or display instrument connected in such a way that the difference in the instrument all measured quantities corresponding to the earth fault currents of the switched-on power supply units on the one hand and all the extinguishing currents of the activated extinguishing devices corresponding measured variables on the other hand is effective. Here are those Measured variables which the power supply units or extinguishing devices in operation corresponding, selected by the display elements of the circuit diagram.

Figs. 1 and 2 show an exemplary embodiment for a simple circuit diagram, Figs. 3 and 4 such an embodiment for a more complex circuit diagram, but both are based on the same metrological basis. In the examples, electrical currents are used as measured variables, which are taken from a direct current source of constant voltage, correctly dosed by means of series resistors, selected by means of contacts and fed to a direct current instrument. The currents, which correspond to the earth fault currents of the individual power supplies, are summed up by connecting the corresponding circuits in parallel and fed to one winding of the instrument, which z. B. is designed as a differential ammeter. In the same way, the currents that correspond to the currents of the extinguishing devices are added up individually

and fed to the other winding of the measuring instrument. Here is the arrangement taken so that the instrument is the difference between the two in its windings indicating flowing currents.

It must be pointed out that by different choices of the measured variables used innumerable variants can be achieved and that the invention is not in the

ίο relatively trivial metrological Education, but consists in the principle already mentioned. For example, instead of electrical currents, electrical currents could also be used Voltages are used which, depending on the sign, are switched on and off will. Non-electrical measured variables, for example pressures which move membranes, can also be used for embodiment of the principle can be exploited.

ao Fig. 1 shows one of the simplest circuit diagrams to which the invention can be applied, and can at the same time be understood as a representation of the artificial circuit diagram. It shows a busbar from which two lines go out and to which z. B. a ground fault coil with three taps is connected. The display elements a ₄ and a ₅ indicate which of the two lines is connected to the busbars, the elements a _u a ₂ , a _s , which tap of the ground fault coil is switched on. Fig. 2 shows the associated circuit diagram of the measuring device. In it, S _{1 means} the positive, S ₂ the negative rail of the direct current source, d a differential ammeter for direct current, W ₁ , w _2> w _s , W ₄ and W ₅ three

• Series resistors. The resistor W ₁ , ϊί'ο, w _s is tapped at three points in such a way that the current flowing between the one pole and one of the taps under the influence of the direct voltage is proportional to the coil current of the corresponding tap of the ground fault coil. Likewise, the current flowing in one of the resistors W ₄ or W _s is proportional to the earth fault current of the corresponding line section. The display elements a _x to C _{5 of} the circuit diagram in Fig. 1 control the contacts 1 to 5 of the measuring device in such a way that the associated contact of the measuring device is closed in the position of a display element which corresponds to the closed high-voltage switch. The designations in Figs. 1 and 2 are chosen so that the index of each control element corresponds to the number of the corresponding contact of the control device.

The whole facility leads under the influence of the direct voltage and the With the help of the correct contacts connected resistors of the left winding of the differential ammeter a current which is opposite to the coil current of the tap in operation, the right winding one opposite directed current, which is proportional to the charging current of the switched-on network is. If the compensation is correct, the instrument points to o, if it is incorrectly compensated to a value which indicates how much coil current must be switched on or off.

The arrangement becomes a little more complicated when the heavy current circuit diagram and the corresponding artificial circuit diagram are no longer as simple as in the case of Fig. 1. An example of a complicated circuit diagram, on which the rules to be applied in general cases can be shown, is shown in Fig. 3. Here there are three spatially distant stations of the high-voltage network A, B and C , which are connected to one another by the lines AB, BC, CA. There is a ground fault coil in each of the three stations, each ground fault coil generally having several taps. However, so that the illustration does not turn out to be too complicated, the illustration of several coil taps is not shown here, since the circuit to be used accordingly has already been adequately described by FIGS. Finally, each of the three stations has a number of stub lines that should not be electrically connected to one another. The switching state to be considered for measuring the degree of earth fault compensation is adequately identified by those display elements of the artificial circuit diagram which are identified by the letters a, b, c and numerical indices.

Fig. 4 shows the circuit diagram of the measuring device for the compensation state of the power supply unit connected to station A. The resistors marked with capital Latin letters and represented by rectangles in the figure are dimensioned in such a way that they absorb a current under the influence of the direct voltage, which is proportional to the earth fault current of the associated high-voltage component. In this sense, for example, the resistance A in Fig. 4 corresponds to the earth fault coil of station A in Fig. 3, the resistance B ₃ in Fig. 4 corresponds to the earth fault current of the power branch B _a in station B, the resistance CA corresponds to the earth fault current of the connecting lines CA in Fig. 3 between the two stations C and A. The contacts in Fig. 4 are designated consecutively with Arabic numerals iao regardless of their meaning.

Are all contacts in circuit diagram 4

closed, a current flows through the left winding of the instrument d which is proportional to the coil current of all three earth fault coils, in the right winding a current which is proportional to the earth fault current of the entire network. The contacts are used to correctly change the information on the instrument when power supplies or earth fault coils are switched off. This happens in detail as follows:

The ground fault coil A in station A is connected to the busbars when the indicator O _{1 is} in the closed position. Accordingly, a single contact 1 is sufficient to connect the associated resistor A to the instrument in Fig. 4. The coil J? can be connected to the busbars of station A in two ways. First on the way AB, second on the way CA, BC, accordingly two contacts 2 and 3 connected in parallel are present in the circuit diagram. Contact 2 is closed when the display members ß ₅ and b _5, contact 3, when the display organs O _6, C _5, C _4, b _s are closed. The contacts 4 and 5, which connect the resistance associated with the earth fault coil C to the instrument, are controlled in a very similar manner. Here, too, there are two contacts connected in parallel, because the coil C can be connected to the busbars of station .4 in two different ways.

An exactly corresponding rule applies to the ladder diagram of the right half, in which the resistances corresponding to the earth fault current of the line sections are connected to the right winding of the instrument but with opposite signs. In the order from left to right, the three resistors A _ä , A ₃ and Ai come first, which represent the earth fault current of the also designated stub lines going out from the station νί. They are connected to the busbars of station A when the associated display elements a ₂ , a _a , a _{4 are} in the closed position. Accordingly, a contact 6 or 7 or 8, which are closed when the said display elements (a ₂ , a ₃ , a ₄ ) are closed, is sufficient for the activation of each of the three resistances ^, A _s or A _1. The same would apply to the branch lines B ₂ , B ₃ , J3 ₄ or C ₂ , C ₃ outgoing from the busbars of station B and C , if the busbars of these two stations were connected to the busbars of station A under all circumstances . However, this is generally not the case. The busbars of station B are only connected to those of station ^ when either the display elements a ₅ , i> ₅ or the display elements a _e , c ₅ , c ₄ , 6 _{e are} closed. Accordingly, in the circuit diagram of the device, in series with contacts 9, 10 and 11, which have the same meaning as contacts 6, 7 and 8, there are two further contacts 16 and 17 connected in parallel, which correspond to these two connection options between AB in a similar way, as shown above. In exactly the same way, the busbars of station C can also be connected to those of station A in two ways, and accordingly two further contacts 18 and 19 connected in parallel to the contacts 12 and 13 which switch on the resistors C ₂ , C _{5 are also located in} Line.

The three resistors AB, CA and BC remain to be discussed, which map the earth fault current of the connecting lines with the same designation between the three stations. The first two are connected to the busbars of station A when the display elements a ₅ and a _{B are} closed, so that one contact 14 and 15 is sufficient to switch on these resistors. The line BC, on the other hand, can again be connected to A in two ways, and accordingly two contacts connected in parallel are also provided for switching on the associated resistor.

The general rule on which the arrangement of the ladder diagram is based is easily recognizable from the example in Figs. 3 and 4 and requires no further explanation. A facility similar to that shown in Fig. 4 can be used for each of the stations be created. Are all or some of the stations in line with one another Connection, as shown by the instruments belonging to the connected stations the same on.

A change in the operating voltage and the changes caused by it the real earth fault or coil currents can be changed by a corresponding change the DC voltage of the device either manually or automatically, e.g. B. by means of control devices of a known type, which influence the mains voltage, To be taken into account. The actuation of the individual contacts by the display organs The artificial circuit diagram can be done in various ways, for example by mechanical interlocks or by electrical Control take place. In the latter case, the display organs and the measuring device can easily be spatially separated.

Various solutions are also possible in the case of electrical transmission,

for example, each of the display elements of the artificial circuit diagram can, in its closed position, excite an associated relay winding of the measuring device with the aid of an auxiliary contact. Each relay then closes a number of contacts. The number of these contacts depends on the meshing of the network. For example, the display element a ₅ corresponds to six con-

jo clocks, namely contacts 2, 5, 14, 16, 19 and 20. Each schematically drawn contact in Fig. 4 consists in this solution of a number of contacts connected in series as many as the control organs must be closed for its closure. So there is z. B. the contact 3 consists of four individual contacts connected in series, one of which is located on the relays which correspond to the display elements a _B , c ₅ , c _it b _e. ,

It is also possible to proceed in reverse and, instead of each of the display elements, arrange a relay for each of the contacts, so that each contact is closed when the associated relay coil is energized. In this case, the relay coil of any contact is excited via a series connection of auxiliary contacts which are located on the display elements. For example, only contact 3 is closed by a relay coil and this relay coil is excited via the series connection of 4 auxiliary contacts, one of which is located on each of the control elements ß ₆ , c ₅ , c ₄ , & _e .

Besides the measuring instrument, which shows the respective degree of compensation, can you can still arrange further devices, which when falling below a certain Degree of compensation actuate an alarm signal or switching or control devices control which automatically switch on further earth fault extinguishing devices "or - at Overcompensation - switch it off so that it corresponds to the respective switching status of the network, the required degree of compensation is automatically set.

Claims (3)

Patent claims: 1. Device for determining the degree of earth fault compensation of high-voltage networks, characterized in that in a measuring and display instrument the difference between one of the total earth fault currents of the switched on Power supplies corresponding measured variable on the one hand and the total extinguishing currents on the other on the other hand, the measured variable corresponding to the switched-on extinguishing device is effective and that the individual measured variables are each generated by a network simulation, each of which by relay, that of the position of auxiliary contacts on the display elements of the switching state of the network reproducing circuit diagram are dependent, with the network is controlled in the same direction. 2. Device according to claim 1, characterized by additional devices, z. B. Relays, which activate an alarm signal when a certain degree of compensation is not reached or control switching or regulating devices that act on the earth fault extinguishing devices works. 3. Device according to claim 1 and 2, characterized in that the voltage the auxiliary power source feeding the auxiliary circuits can be adjusted manually or automatically according to the fluctuations in the mains voltage. For this purpose τ sheet drawings