DE579838C - Switching arrangement, which is fed from two current sources with periodically changing currents, to determine state variables of one current from the known variables of another or to bring about an effect from the interaction of two currents, in which the two current sources act on two DC circuits via rectifiers - Google Patents

Description

Switching arrangement consisting of two current sources with periodically changing Streams is fed to determine the state variables of a stream from the known Sizes of another or to bring about an effect from the interaction two currents, in which the two current sources are fed to two DC circuits via rectifiers Acting rectifiers, especially dry rectifiers, are used in measurement technology has been used many times to measure alternating currents. The majority of the for Circuits that have become known for this purpose are merely concerned with the fact that Rectifiers are used to rectify an alternating current, which is a direct current instrument is fed. It has also been suggested to use product or ouotient knives for To create alternating current by the fact that one coil of a product or Quotient device with the help of rectifiers fed a direct current that a alternating current flowing in one line is proportional, while the other is coil this device is supplied with a current with the help of rectifiers, which the corresponds to the voltage prevailing in the measuring circuit. With these devices it only comes in Measuring instrument for the interaction of the two electrical quantities. The rectifiers are not involved in the combination of these variables. Subject of the present invention is a switching arrangement that is fed from two current sources with variable currents is and the determination of state variables, the one stream from the known Magnitudes of the other or to bring about an effect from the interaction of two Currents are used in which the two current sources are fed to two DC circuits via rectifiers act. The interaction of the two currents is however with the help of the rectifier itself brought about by the fact that, according to the invention, the two current sources in such a way are connected that the voltages effective in one circuit of the add the two power sources geometrically, while they are in the other circuit subtract geometrically from each other, and in which the circuit; z. B. using of rectifier bridges, is designed in such a way that both half-waves of the alternating currents enter every DC circuit. Two embodiments of the new switching arrangement are illustrated in FIGS. In the exemplary embodiment According to Fig. i, I is one and II is the other direct current flow. For the introduction the currents fed to the circuit in the DC circuits I and II are used by transformers 1, z, 3 and 4., of which the transformers i and a with their primary windings are connected to the power source 5, while the transformers 3 and q. with their primary windings are fed by the current source 6. The secondary windings 1b and 2v of the transformers i and 2 are at their ends via the lines 7 and 8 connected to each other. The centers of the secondary windings are fv and 2G tapped and through the line 9, in which the secondary windings of the transformers 3 and 4 are conductively connected. In this way a bridge is formed, its central branch the line 9 forms and at its diagonal points the DC circuits I and II are connected, while their common return leads to the central branch 9. In the lines 7 and g are symmetrical to the connection points of the DC circuits I and II each have two rectifiers 1o, r i and 12, 13 inserted, their forward directions are opposed to each other in each line. The same effect would one also achieve when the blocking directions of the rectifier 1o and rr and also the the rectifier 12 and 13 would be directed opposite to each other. In the DC circuit I and the DC circuit II are each a resistor 14. and 15. 16 is a DC current meter, that with its one terminal to the resistor 14 and with its other terminal the resistor 15 is connected.

The circuit becomes expedient in terms of the constants of the two Circles are built up symmetrically, transformers i and 2 switched so that in one cycle, starting with the rectifier 1o, over the Secondary windings 2U and Iv the voltages induced in these have the same sense of direction exhibit. Likewise, the transformers 3 and 4 are connected so that the in the secondary windings of these transformers induced voltages the same Direction, based on the line g own. This results in the following mode of action the circuit:.

Assume that the circuit is only fed by the current source 5. In this case as well as otherwise, they have the direct current circuit I and the direct current circuit II flowing currents the directions determined by the next to the resistors 14 and 15 'arrows are indicated, the currents are also the same size. As a result, occurs between the connection points of the direct current meter 16 with the resistors 14 and 15 no voltage difference, so that the DC current meter r6 remains de-energized.

Conversely, if the circuit is only fed by the current source 6, then the currents flowing through DC circuits I and II are also the same large, as a result, the DC current meter 16 remains de-energized in this case as well.

If, on the other hand, the circuit is fed by both current sources 5 and 6, this results in the following mode of operation: It is assumed that the supplied currents have the same phase position and the same curve shape. The relationships that arise here are illustrated in the vector diagram of FIG. Suppose that the voltages introduced into the direct current circuit I from the current sources 5 and 6 5 'and 6' add up geometrically, that is, combine to form the resultant I '. The corresponding voltages 5 'and 6' of the direct current circuit II are then geometrical subtracted from each other, thus result in the resultant II '. As a result, the Current in the direct current circuit I is always greater than the current in the direct current circuit II, since the resultant I 'always acts on the DC circuit I, namely during the one half cycle via the rectifier 1o and during the other half cycle via the rectifier 1i. The resultant II 'always acts in the same way the direct current circuit 12 or via the rectifier 13. As can easily be seen, occurs as soon as the current of DC circuit I outweighs that of DC circuit II, a potential difference between the connection points of the measuring device 16 to the Resistors 14th and 15 on. The measuring device 16 therefore shows a certain deflection, the, provided that the voltage introduced by the power source 5 into the DC circuits is greater than the voltage which is introduced by the current source 6, i clearly is determined by the magnitude of the voltage originating from the current source 6.

If the alternating current supplied by the power source 6 is compared to the the previously assumed case shifted by 180 ° in phase 1, then how one has can easily be deduced from the diagram of FIG. 2, with the result that the resultant II 'is greater than the resultant I' and therefore that of the direct current circuit II flowing through it Current 1 is always greater than the current in the direct current circuit I. Correspondingly shows the meter 16 again a rash of the same size but opposite Sign as in the case given above.

It is now assumed that the supplied from the AC power source 6 Current or the voltage induced by this current in the direct current circuits go ° phase shifted with respect to the effective in the secondary windings 1b and 2b Tensions. Figure 3 illustrates the vector diagram for this case. How yourself thereupon results are those effective in DC circuits I and II Tensions I 'and II' have the same absolute value, but have one mutual phase shift that is greater than 0 and less than i8o °. From this it follows that the mean values of the currents flowing through the two DC circuits are equal, while the instantaneous values of the currents im. general however are different.

Since the DC current meter does not work at frequencies that are not too low the rapid changes in the instantaneous values follow, rather its setting by the difference in the mean values of the resistors 14 and 15 flowing through Currents is determined, but these mean values are the same, so shows the DC meter 16 at go ° phase shift between the current source 5 and the current source 6 resulting from voltages is not a factor.

Fig. 4 illustrates the vector diagram for the case that the phase shift between the voltages resulting from the current sources 5 and 6 between o and go ° or go and 18o °. One can easily refer this case to the one above to Fig. 2 and 3 discussed cases back by, as in Fig. 4 with dashed lines Lines indicated, the vectors of the voltages 6 'in two components 6a' and 61, ', one of which falls in the direction of the vectors 5' and the other perpendicular to these stands. As discussed with reference to FIG. 3, the exercise perpendicular to the vectors 5 ' pending vectors 6v have no effect on the measuring device 16. The vectors 6d, however sit with the vectors 5 'in the same way as in Fig. 2, the vectors 5' and 6 'together to resultants, the difference in size of which determines the deflection of the Measuring device 16 is dependent. As can easily be seen from Fig. 4, the deflection is of the measuring device 16 is smaller than the deflection in the last-mentioned case; the occurs when, as assumed in Fig. 2, the vector 6 'in the direction of the vectors 5 'falls.

5 illustrates an embodiment of the new circuit arrangement, which in terms of their mode of operation are completely identical to the Fig. I, but is simpler in structure compared to the first embodiment. So far the parts used in the second embodiment are the same as those according to FIG. the same reference numerals are used. Accordingly, again is a DC current meter 16 with its two terminals connected to a resistor 14 and 15, respectively the resistor 14 in turn in the DC circuit I and the resistor 15 in the DC circuit II is present. The DC circuits I and II are connected to a rectifier bridge 2o or 21 connected in the Graetz circuit. The rectifier bridges 20 and 21 each form a branch of a bridge, the other two branches through the Halves 22b and 22, the secondary winding of the transformer 22 are formed, whose primary winding 22 ″ is fed by the current source 5. In the central branch the last-mentioned bridge is the secondary winding 23b of a transformer 23, the primary winding 23 ″ of which is fed by the current source 6. As already mentioned, the operation of this circuit is completely identical to that on Hand of the diagrams of Fig. 2 to 4 described mode of operation of the embodiment according to Fig. i.

According to the above, the following possible applications are the The new circuit is easy to understand: For alternating current measurements it offers e.g. B. because of the greater sensitivity of direct current meters Advantages, the alternating current to be fed to a DC current meter via a rectifier arrangement. As known, is the characteristic of the rectifier in its lower part is curved and becomes 1 straightforward only above a certain size of the current passed through. This is especially true for tube rectifiers. Similar conditions are however also in the case of dry rectifiers, which, as is well known, 1 only above a certain level Current strength for measuring purposes can be measured with sufficient accuracy. For these reasons it offers it is difficult to measure alternating currents with a rectifier and a direct current meter, provided that 1 the measuring currents are very small. These disadvantages are offset by the one described above Circuit eliminated.

In this use z. B. the power source 5 as an auxiliary power source, while the measuring current is passed through the primary windings of transformers 3 and 4 or with reference to the embodiment of Figure 5 on the primary winding of the transformer 23 is directed. Here 1: Provision must be made that the measuring current in a fixed phase relation to the Auxiliary streams is appropriate so that the voltage introduced into the DC circuits by the measuring current is in phase or shifted in phase by 180 ° from the auxiliary power source into the direct current circuits introduced tensions. In this case, as above with reference to the diagram explained according to Figure 2, the deflection of the DC device 16 clearly from the Size of the measuring current dependent. The auxiliary current is only used to, so to speak the measuring current above the curvilinear part of the rectifier characteristic to carry the rectifier through without, however, the auxiliary current in the display of the measuring device. To the required fixed phase relationship of the measuring current to bring about the auxiliary stream, it is useful in many cases, provided that the Ratios of the measuring circuit make this possible, the auxiliary current from the same current source can be seen from which the measuring circuit is fed. It should also be noted that for the specified measuring method can be used with particular advantage are.

The specified circuit can be used for frequency analysis or determination the harmonics present in an alternating current are used. It be with Referring to Fig. I, assume that the current source 5 is the circuit with a current food whose frequencies are to be determined. In this case the frequency will be the current supplied by the current source 6 into the circuit is gradually increased, until the frequency is approximately with a partial frequency of that supplied by the power source 5 Current matches. This can be seen from the fact that the pointer of the DC device 16 slowly swings back and forth. The relationships that occur here are shown in the diagram 6 illustrates. The voltage harmonics you are looking for, based on the secondary Windings of transformers i and 2, is denoted by 5 ', while that of the Current source 6 introduced voltage, based on the secondary winding of the transformers 3 and 4, denoted by 6 '. Do the frequencies of the voltage vectors match 5 ' and 6 'do not match perfectly, e.g. B. the frequency of the vectors 5 'greater than those of the vectors 6 ', then the vectors 5' rotate in the direction of the depicted Arrows relative to the voltage vectors 6 '. In the size of the DC circuits The currents flowing through I and II thus occur according to the changes in the resultant I 'and I1' (Fig. 6) beats, and oscillates according to these beats the pointer of the DC device 16 slowly back and forth. The maximum deflection of the measuring device is achieved, as can easily be seen from the diagram in Fig. 6, when the vectors 5 'have rotated so far that they are in the direction of the vectors 6 'fall. Here, the deflection of the measuring device is also a measure for the Size of the sought voltage harmonics 5 '. Becomes the frequency of the power source 6 still regulated until it matches the frequency of the harmonic being sought, so the measuring device stops in a certain position, there yes in this case a relative rotation of the vectors 5 'with respect to the vectors 6' no longer takes place. The standstill of the measuring device 16 after previous slow pointer fluctuations So there is a clue that now the frequency of the power source 6 with the the desired harmonic of the voltage of the power source 5 matches.

The new circuit is of particular importance as a receiver circuit for transmission devices of commands, measured values and the like, which use the two-pulse method operate. For facilities that are operated according to this procedure, address the receiving devices only if they are simultaneously from two different Places each received one or more impulses. At the institutions mentioned If there are several senders, for example via the same transmission line, with the receiving station connected, on which several receiving devices are connected to the line.

In Fig. 7 the circuit is at the receiving point, as far as it is here interested, illustrated. To simplify the illustration, there are only two receiving devices accepted; Of course, however, a larger number of receiving devices can also be used connected to the same trunk line.

The receiving circuits A and 13 are connected to the trunk line 30. In terms of their structure, the circuits A and B correspond completely to the circuit according to FIG. 5. To designate the individual parts, the same reference numerals are used as there, insofar as they correspond to the embodiment according to FIG. 5. The primary windings 23 ″ of the transformers 23 of the two circuits A and B are connected to the long-distance line 3o. The transformer 22 of the circuit A is continuously supplied with current impulses via the line 3i during operation of the system, the course and time interval of which are shown by curve a in FIG . is illustrated. 8 in the same way, "the transformer -erden 2s of the receiving circuit B in the operation of the system supplied power surges, the course and sequence in time by the curve b of FIG. 8 illustrates. As seen from a comparison of curves a and As can be seen in b, the current surges fed to circuit A via line 31 are out of phase with the current surges fed to circuit B via line 32, in such a way that, while a current surge runs via line 31, line 32 is de-energized.

When the transmitting device associated with the receiver A is switched on, the latter sends over the long- distance line 30 current impulses, which are illustrated in FIG. 8 by the curve cc, in phase and mutual time interval. As can be seen from this, the current surges of curve as are in phase with the current surges of curve a, while they, like these, are out of phase with the current surges which are fed to circuit B via line 32. Curve b of FIG. 8 illustrates the course of the current surges which are transmitted via the trunk line 3o when the transmitter that is assigned to the receiving circuit B is switched on. As can be seen from the illustration in FIG. 8, these current surges are in phase with the current surges which are fed to circuit B via line 32. Instead of the DC meter i6 of the circuit according to FIG. 5, the receiving circuits A and B of FIG. 7 each have a receiving relay 33 or 3q. B. by reloading or charging a capacitor via a DC current meter, set this according to the pulse frequency to a certain deflection.

The mode of operation of the device according to FIG. 7 is as follows: During operation of the system, the circuits A and B are continuously supplied with pulses via lines 3 i and 32, the course and mutual phase position of which are illustrated by curves a and b in FIG . As explained above for FIGS. I and 5, in this case the currents in the resistors are 1d. and 15 of each circuit A and B are the same size, so that the receiving relays 33 and 3q. As long as the trunk line 30 is de-energized, are not affected. If the transmitter, which is assigned to the receiving circuit A, is put into operation, then current impulses run through the primary winding 21, the transformers 23 of the circuits A and B, the course of which is given by curve a in FIG. Since these current surges are in phase with the current surges a, this has the consequence that the relay 33 of the receiving circuit _A is actuated; the relay 34 of the receiving circuit P, on the other hand, remains at rest, since the current impulses a i are out of phase with the current impulses b go °, that is to say the individual current impulses enter this circuit one after the other, but not at the same time.

Conversely, if the transmitter assigned to the receiving circuit B is put into operation while the other transmitter is shut down, then current surges run over the line 30 , the course of which is indicated by the curve bs in FIG. Since these current surges are in phase with the current surges which are fed to the receiver circuit B via the line 32, the receiving relay 34 is actuated while the receiving relay 33 of the receiving circuit A remains de-energized. As is easy to see, both transmitters can be put into operation at the same time. In this case, current surges run over the line 30, which follow the curve as and the curve b. belong.

As can be seen from the illustration, it is for the transmission facility essential that the pulses sent by the transmitters over the trunk line -ein have certain phase relation to the pulses that of the associated receiving circuit be fed via line 3 i or via line 32. That purpose Serving circuits or devices have with the circuit arrangement according to to do nothing to the invention per se; there is therefore no need to go into it further here.

In the diagram in FIG. 8, the positive polarity was assumed for the pulses of the individual curves. If the pulses ca introduced with positive polarity in the circuit A and the pulses a, sent once with positive and then with negative polarity, this has the consequence when using a polarized receiving relay instead of the usual relay 33 that the polarized relay once in one Sense and then actuated in the other sense. It is thereby possible, in accordance with the polarity of the pulses a sent into the long-distance line 30 , of two receiving devices assigned to the circuit A to influence one or the other via a polarized relay. The same applies to circuit B.

There are a number of other uses for the new ones Circuit arrangement; for example, the circuit for phase comparison or can also be used to control machines, for example by controlling is derived from the deviations of an actual frequency from a target frequency. Here two currents are fed to the circuit, one of which is the actual and the other of which has the setpoint frequency. As can be easily seen from the description above As the operation of the new circuit shows, it is not necessary to change the circuit to be built like a bridge. rather, it is also possible to split the bridge in two to dissolve completely separate alternating current circuits, with one alternating current circuit one direct current circuit and the other alternating current circuit the second direct current circuit is connected. It is, however, in order to use as few transformers as possible get along, expediently to build the circuit as in Fig. i or as in Fig. 5. The circuit according to FIG. I can be simplified in that the transformers 3 and q. to a transformer with two secondary windings or with a single one are combined in the middle of the tapped secondary winding. Of course but you can also transform transformers i and 2 into two separate transformers dissolve. There is also the possibility, in the embodiment according to FIG. 5 to use two separate transformers instead of the transformer a2 secondary windings are of course to be switched again as shown in the illustration 5, the winding halves 22t, and 22 ,. It is also easy to see that in the embodiment of FIGS. i and 2, the primary windings of the transformers i and 2 can also be connected in parallel instead of in series. .

As can already be seen from the illustration above, it is for different Uses of the new circuit do not need two separate power sources 5 and 6, but in some cases it can be a common power source to be used. When in the description and in the claims there is talk of is two power sources, this can also be understood as indirect power sources such as voltage dividers, transformers, bridges or other circuits, which take the place of the current sources 5 and 6 indicated in FIGS. i and 5 and which in turn can be connected to one and the same power source. E.g. one becomes such a circuit especially for the remote transmission device choose according to Fig.7, in that it is advantageous to use the sending and receiving points connecting AC network used as a common output power source.

Finally it should be mentioned that, if you z. B. in the circuit according to Fig. i, the primary windings of transformers i and 2 are not connected in series, these primary windings, instead of connecting them to the same power source 5, too can be connected to two separate power sources that are operated synchronously, so that the primary current fed to the transformer i in phase and waveform essentially with the current fed to the primary winding of the transformer 2 matches.

Claims (7)

PATENT CLAIMS: i. Switching arrangement consisting of two power sources with periodically changing currents is fed to determine state variables of a current from the known quantities of another or to bring about a Effect from the interaction of two currents, in which the two current sources over Rectifiers act on two DC circuits, characterized in that the two power sources are connected in such a way that they are in the one circuit the effective voltages of the two power sources add up geometrically while they are subtract geometrically from each other in the other circuit, and in which the circuit, z. B. using rectifier bridges, is designed such that both Half-waves of the alternating currents enter every direct current circuit. 2. Switching arrangement according to claim i. characterized by four primarily fed by the one power source Transformers, their secondary windings, in the same sense of direction of their voltages successively, the branches form a bridge, each point of the one Diagonal point pair between two rectifiers, their forward directions or Blocking directions run to the diagonal point, is arranged and. at these diagonal points the DC circuits are connected, while their return lines or forward lines lead to the central branch of the bridge, in the symmetrical to this connection point the secondary windings of two transformers are connected, primarily from the second power source are fed. 3. Switching arrangement according to claim 2, characterized characterized in that several of the transformers correspond to one transformer under Tapping a secondary winding are summarized or several of the in the bridge laid secondary windings have a common primary winding. Switching arrangement according to claim i, characterized in that the two DC circuits at each a rectifier bridge are connected, which in turn the Form branches of a bridge, in the other two branches of which the secondary windings one transformer each, while the secondary winding is in the middle branch of this bridge of a third transformer. 5. Switching arrangement according to claim q., Characterized characterized in that the two transformers whose secondary windings are in the Outer branches of the bridge are arranged to form a transformer with two secondary windings or are combined with a secondary winding tapped in the middle. 6th Switching arrangement according to one of Claims i to 5, characterized. that instead two power sources a common power source is used. 7. Switching arrangement according to one of claims i to 5, characterized in that each of the two current sources or one of the same is resolved into several synchronously operated current sources. B. switching arrangement according to one of claims i to 7, characterized by a direct current measuring device, a relay o. G. Switching arrangement according to one of Claims i to;, characterized in that the connection of the direct current measuring device, the relay or the like is selected so that when the one current source is de-energized, the connection points have the same potential and the direct current measuring device thus remains de-energized. ok Use of the switching arrangement according to one of Claims 1 to 9 as a receiver circuit in telecontrol systems operated according to the two-pulse method, in particular telemetry systems.