DE619518C - Device for determining the degree of compensation in high-voltage systems - Google Patents

Description

GERMAN EMPIRE

ISSUED ON OCTOBER 10, 1935

REICH PATENT OFFICE

PATENT LETTERING

CLASS 21c GROUP

Addition to patent 615

Patented in the German Empire from March 9, 1929 The main patent started on January 12, 1929.

The main patent 615688 relates to a device with which the Erdschhißkompensationsstatus one with extinguishing devices provided network is displayed.

The invention is concerned with the solution of an extended problem, namely with the display of the compensation status of high-voltage networks built up from double lines, in which the two .branches of the double lines in the whole network or in a part are not electrically connected during operation. Often in such a Network set the task that on the one hand with earth faults in one or the other of the both sub-networks, the earth fault current can be reduced to the lowest possible level and that on the other hand, if an earth fault occurs in one of the two sub-networks, in the other sub-network no impermissible zero point voltage due to capacitive influence should be influenced. Known devices, which serve as generalizations, serve this purpose the also known ground fault coil can be understood.

The principle of such a device is shown in Fig. Ι, in which C means the partial capacity of one, C " the partial capacity of the other subnetwork to earth and C the mutual capacitance of the two subnetworks. D ' and D" are two earth faults 3 " coils which, if correctly matched to the associated capacitances C and C ", essentially make the earth fault currents disappear in each of the two subnetworks in the event of an earth fault. The choke D, which is matched to the capacitance C , is used for mutual decoupling of the two systems or, as one can also express it, for cross-compensation, so that if a ground fault occurs in one of the two sub-networks, the zero-point voltage infiltrated in the other sub-network is applied to one Smallest value is depressed. A number of other circuit variants have become known which solve the task of earth fault compensation in both networks and cross compensation using chokes or transformers or both. However, it is sufficient to first describe the invention in its application to the circuit according to Fig. Ι and then specify the necessary changes if another equivalent occurs in place of this circuit.

To understand the invention, in addition to the basic diagram in FIG. 1, there is also the

*) The patent seeker stated as the inventor:

Dr. Hans Piloty in Berlin-Wilmersdorf.

Knowledge of the actual circuitry of the network is required. An example of such a circuit is shown in Fig. 2. In the course of a double line consisting of sections L ₁ , L ₂ , L _3, there are a number of stations, two of which, namely stations St ₁ and St ₂ , are shown The schematic representation is unipolar, and the letters L ₁ and L ₁ " identify the two branches of the section L _{1 of} the double line. The same applies to the other sections. Each station has double busbars, e.g. B. the station .SY ₁ the busbars S ₁ and S ₁ "; in the operating case shown, the two systems work independently of each other. Accordingly, a special transformer is connected to each of the two busbars in each of the stations, for example in station V ^ i ₁ the transformers T ₁ and T ₁ ". The zero points of the high-voltage winding of these two transformers are connected to one another and to earth by a choke circuit as shown in Fig. 1, those "25 of the transformers of station St _1, for example, by chokes D ₁ , D ₁ and D ₁ ". The chokes are usually adjustable, e.g. B. by winding taps. The small rectangles in the circuit diagram of Fig. 2 mean switches, the position of which is decisive for the operating state of the line sections and coils. Of course, there can also be more switches. However, only the absolutely necessary are drawn in order to simplify the representation.

The invention relates to a device which the switch positions and Coil taps indicates the corresponding compensation state of the network. For the In contrast to the main patent, the assessment of the compensation status is now the Specification of a single instrument is not sufficient. Rather, it requires the Compensation state of each of the three from one capacitor each and one in parallel switched choke coil formed partial circles of Fig. 1 to display separately. Accordingly the device according to the main patent is doubled and by according to the invention a special facility 'added to determine the degree of cross compensation.

An exemplary embodiment which corresponds to the circuit diagram of Fig. 2 is shown in Fig. 3. The uppermost part of Fig. 3 shows a blind diagram formed from auxiliary rails, the connections of which correspond to the high-voltage circuit diagram. Both branches of the double lines are assigned two sets of rails, the individual parts of which correspond to those with the same names in Fig. 2. For example, L ₁ in FIG. 3 denotes that rail which corresponds to the line section L ₁ in FIG. 2, S ₂ ″ that set of rails which corresponds to the busbar S ₂ ″ in FIG. Both halves of the double line are thus represented by a set of double rails in a blind diagram. The contacts k in Fig. 3 correspond to the similar high-voltage switches shown by small rectangles in Fig. 2. The busbar system can be energized from an auxiliary power source, and the power is supplied to those sections which correspond to the busbars of such a station in which there are compensation coils. This power can be supplied through a changeover switch or, as assumed in Fig. 3 for the sake of simplicity, through a plug s which can be plugged into sockets of the station rails. For example, if the plug is plugged into the socket of station 1 (rail / and .SV "), the measuring instruments are supplied with the associated values (conductance of capacitance and inductance of each of the two halves to earth, mutual capacitance and inductance) of those line sections which The connection is made through the intermediary of the contacts k, the position of which corresponds to the position of the high-voltage switch and which are either correctly set manually or positively controlled by a remote control device.

The capacitive resistances of the three decisive partial capacitances (according to Fig. 1) of each line section as well as the reactances of the three sub-stages of each compensation coil set are represented by the correspondingly designated direct current resistances in Fig. 3. The latter can be regulated according to the operationally variable - taps of the coils represented by them. Their resistance value is adjusted either by hand or by remote control or by remote measurement to the respective set reactance value of the real coils. The three instruments T ₁ , J ₂ no and J ₁₂ reflect the compensation status of the three partial circles. Each of the three instruments is designed as a differential ammeter. The measurements of the degree of earth fault compensation of each of the two systems are carried out in the manner known from the main patent. The left winding of each of the two instruments J ₁ and Z ₂ is supplied with a current which is proportional to the sum of the conductance values of all resistors C and C " . This sum is in turn proportional to the earth.

short-circuit current of that power supply unit of one or the other branch of the double lines which is connected to the busbars of the selected station. The right winding of these two instruments is fed a current in the opposite direction, which is proportional to the sum of the conductance values of the resistors D ' and D " , which in turn correspond to all earth-fault coils connected to the selected busbars. Each of the two instruments therefore shows the Difference between the earth fault current and the compensation current of one of the two halves of the double line.

The device for measuring the degree of cross-compensation is new. It is analogous trained in the same way, only the fact must be taken into account here, that both mutual capacity

ao of a certain line section and the conductance of the cross compensation coil of a certain station are only of influence for the compensation status of the selected station if both one and the other line branch of the section or both one and the other busbar of the station with the Busbars · of the selected stations are connected in pairs. This task is solved according to the invention in that the Abbil training resistances for 'the mutual capacitances or inductances two-pole with the intermediary of the blind scheme with the rest of the circuit in contrast to the earth fault compensation measurement serving resistors, which with the power source or the relevant measuring instrument are single-pole firmly connected. For example, in the circuit of Fig. 3, the imaging resistances C ₁ , C ₂ for the mutual partial capacities of the individual line sections are on the one hand via the topmost rail of the blind scheme belonging to system 1 (plug contact α) with the positive pole of the power source, on the other Side connected to the lowest rail belonging to system 2 (contact d) and the left winding of the associated instrument with the negative pole of the power source. The imaging resistances D ₁ , D ₂ for the mutual inductances protrude analogously on one side via the second rail belonging to the system 1 (contact b) and the right winding ^{1 of} the instrument J ₁₂ with the negative pole of the power source on the other side the third rail belonging to system 2 (contact c) in connection with the positive pole of the power source.

Cross compensation does not always take place according to the principle shown in Fig. 1.

Another frequently used arrangement is illustrated by Fig. 4, for example. It differs from that shown in Fig. Ι in that the triangle formed from the throttle flushes D, D ', D "is replaced by the equivalent star D _a , D _b , D _c . In this case, the one in Fig. 3 The circuit shown cannot be used without further ado, since for the degree of compensation of each of the three capacitances C, C ″ and C, not just one, but all three choke coils are of influence. In order to obtain the desired result, namely the display of the degree of compensation of the three capacities, according to the invention, regardless of the actual circuit, the compensation status of the equivalent circuits according to Fig the circuit of Fig. 1 would be present. How this can be done in detail is explained with reference to Figs.

Are 'the reactors z. B. switched according to Fig. 4 and their reactances mapped again by equivalent resistances, the task is to create three currents for each coil set, which are proportional to the conductance of the equivalent delta connection. Fig. 5 a shows the star-connected three resistors a, b, c, which correspond to the reactances of the three choke coils D _a , D _b and D _c in Fig. 4, while in Fig. 5 b those from the three resistors x, y, ζ existing equivalent delta connection is shown. The resistance χ of the delta connection can be calculated from the resistances of the star connection according to the relationships

x = b - \ - c- {

a.

to calculate. If, on the other hand, a voltage U _{x is placed} between points α and b of the star connection , as shown in Fig. 5a, and the external terminals of the resistors α and c are short-circuited via an ammeter, then there is between the applied voltage U _x and the voltage flowing through the instrument Current J _x the relationship

However, if one compares the two equations, one can easily see that for a given voltage U _x, the current J _x is proportional to the conductance of the resistor χ. The same result is obtained, as can easily be shown, if the voltage and current connections are interchanged, i.e. the voltage is placed between the terminals α and c and the ammeter between the terminals α and b . Currents which correspond to the conductance of the resistors y

and z correspond to the delta connections, is obtained by interchanging the connections cyclically.

If the rule found is applied to the case of the compensation measurement, a circuit is obtained which is shown in principle by Fig. 6. -This circuit contains mapping resistors for the chokes D _a , Dt, D ₀ of Fig. 4, namely two mapping resistors for each of the chokes as well as the three instruments J ₁ , J ₂ and J ₁₂ , which are also in the circuit of Fig. 3: occurred. The left coils of this differential ammeter are fed in exactly the same way as in Fig. 3, but that of the right coils in the manner shown, which corresponds to the rules of Fig. 5 a and 5 b. In this simple representation, no consideration is given to the selection of those of several parallel-connected coil sets which are connected to the selected station, the compensation state of which is to be measured.

The one that also satisfies this requirement and corresponds to the circuit shown in Fig. 3 Circuit is shown in Fig. 7. It contains nothing more than the analogous application the conversion circuit according to Fig. 6 for the star-triangle conversion to the Circuit of Fig. 3. The designations are the same with the exception of the imaging resistances for the chokes, which are now Fig. 4 correspond. The circuit for the mapping resistances of the partial capacities has stayed the same. Only the circuit for the mapping resistances of the chokes has changed according to Fig. 6. With the help of this facility, the Officials charged with monitoring the compensation status recognize whether the taps are occurring the choke coils are set correctly or not for the respective network status. But he can just in case not easily ascertain that the desired degree of compensation is not available, what switchover «! must be undertaken in order to achieve the desired state, because when switching over a throttle, the coordination of all three resonance circuits changes. The official would therefore have to rely on switching the Choke coils in the network to determine how the compensation status can be improved. This method is particularly cumbersome when the individual throttle sets in different stations remote from the command post are set up.

In order to obtain clues for the required change in the coil tap To make it easier, a so-called trial circuit diagram can be provided, i. H. one . Device, which corresponds to that shown in Fig. 4 or Fig. 7, but in the the switch positions and coil taps do not correspond to the actual switching status of the network, but by hand, e.g. B. with the help of switch plugs, can be set arbitrarily. Means Such a facility can be used by the officer concerned without any switching to make in the network, to simulate and on any switching states determine in this way how the compensation coils are to be switched over so that the desired state occurs. The trial facility can sometimes be combined with the measuring device according to Fig. 4 or Fig. 7.

Claims (5)

Patent claims: i. Device for determining the degree of compensation in high-voltage systems according to patent 615 688, characterized in that in their application for such networks that are operationally connected in two or more non-conductive, each other capacitive influencing sub-networks can disintegrate and 'in which in a known manner by means of inductors or transformers or their combination compensate for the earth fault current of both subnetworks. is sated (earth fault compensation) as well as the capacitive effect of one sub-network on the other is canceled in the event of an earth fault (cross compensation), for Each sub-network has a special measuring device for the degree of earth fault compensation and also a measuring device for the degree of cross compensation is provided. 2. Device according to claim 1, characterized in that three pairs of measuring circuits controlled by a mimic diagram are available, of which the first is the difference in the conductance of the capacitance to earth on the one hand, the inductance against earth on the other hand of the first sub-network, the second the corresponding one Difference of the second sub-network, the third the difference in the conductance values of the mutual capacitance on the one hand and the mutual inductance on the other hand in one measuring instrument for display brings. 3. Device according to claim 1 and 2, characterized in that the the mutual partial capacitances or inductances corresponding imaging resistances double pole under switching development of the mimic diagram with the other parts of the measuring circuit in connection stand. 4. Device according to claim 1 to 3, characterized in that when used for those networks in which the earth fault compensation of both subnetworks as well as the cross compensation by one or several sets of star-connected reactors are carried out, their three connection points or with a zero point of one sub-network, a zero point of the other sub-network and earth stand, the measuring circuits corresponding to the choke coils are connected so that the measuring instruments are measured which are the conductance values of the inductance to earth of a sub-network, the inductance to earth of the other sub-network as well as the mutual Inductance are proportional. 5. Device according to claim 1 to 4, characterized in that each Choke set one or more sets of three star-connected mapping resistances proportional to the reactances of the choke coils correspond with a voltage source and with the! Clamps of the measuring instruments are related that in each measuring instrument a current flows which corresponds to the conductance of a Side of a resistance triangle that corresponds to the existing resistance star is equivalent. For this purpose ι sheet of drawings