DE1193146B - Arrangement for setting the response threshold of a ripple control receiver - Google Patents

Description

Arrangement for setting the response threshold of a ripple control receiver In ripple control technology, control pulses with the highest frequency are fed into the existing high-voltage network superimposed and on this power network from the transmitter point to a multitude directed by remote receivers.

This ensures the proper functioning of the entire system the following technical conditions must be met: The The minimum response voltage of the receiving equipment must be higher than the maximum that can be expected Interference level. This interference level now usually fluctuates very strongly both in function the time as well as a function of the place. To be taken into account are of course the most unfavorable time and the most unfavorable receiving location. The transmission power must be so large that the control impulses are always and everywhere in the network to be controlled arrive at a level that is above the minimum response voltage of the receiving apparatus lies. In practice, the reception level is also subject to strong fluctuations subject to place and time, e.g. B. by connecting and disconnecting compensation capacitors high capacity. With this second condition, too, of course, the the most unfavorable time and the most unfavorable receiving location are taken into account.

Since now both the interference level and the level in the power grids the control impulses are subject to extraordinarily large temporal and local fluctuations are too proportionate if the two conditions listed are taken into account large transmission powers, especially when all receiving sets for reasons of Normalization have the same minimum response voltage, which is above the must be the highest noise level to be expected.

The present invention is based on the knowledge that in one Network with load changes control and interference voltage are approximately in the same ratio change to each other. A ripple control receiver for networks with variable load is therefore designed according to the invention so that the level of its threshold for the Control voltage automatically adapts to the level of existing interference voltages and is designed to lie above it by a security amount.

An expedient implementation of such a receiver is to that the capacitor to be charged by the signal voltage via a diode is a capacitor is connected upstream and that the time constants of both capacitors by parallel resistors are set so that the time constant of the upstream capacitor is greater than that of the other capacitor.

Exemplary embodiments will now be given on the basis of the description and the figures of the arrangements according to the characterizing parts of the claims are described. F i g.1 shows the schematic structure of a power network to be controlled, F i g. 2 the percentage drop in interference voltage or the increase in interference voltage in a capacitively loaded low-voltage network, FIG. 3 the electrical scheme a receiving arrangement, FIG. 4 the electrical scheme of a possible variant a receiving arrangement, FIG. 5 the electrical scheme of another possible one Variant of a receiving arrangement.

F i g.1 shows the schematic structure of a ripple control network. The basic circuit diagram of a substation is shown in area 1 outlined by dashed lines shown for high voltage intermediate voltage. Its high-voltage busbar 2 is fed by two high-voltage lines 3 and 4. At the high voltage line 4, for example, a large rectifier 5 is connected. Such large rectifiers, which are used for electrometallurgical or for railway purposes, etc. can, generate very significant harmonics and thus interference voltages for central control systems.

Via the transformers 6 and 7, both the 50 Hz high-voltage current and the aforementioned harmonics (interference voltages) reach the intermediate voltage busbar 8 and from here on via the intermediate voltage lines 9 and 9 ', the low-voltage transformers 10, 10', 10 ", 10"' and 10 "", the low-voltage networks 11, 11', 11 ", 11"' and 11 "" to the individual remote-controlled receivers for the switches to be controlled.

Of the latter, FIG. 1 only a single one is shown with the reference number 12 "' . In fully developed ripple control systems, for example, over a thousand such receivers are to be expected per intermediate voltage network. They are normally connected in all low-voltage networks.

The interference voltages generated, for example, by the large rectifier 5 now suffer very different voltage drops on the way from the intermediate voltage busbar 8 to the various receiving apparatuses (not shown). The size of these voltage drops depends not only on the respective ohmic load on the low-voltage networks from the normal electrical appliances, but also, above all, on the capacitive loads on the individual low-voltage networks. The capacitive load 13 " in the low-voltage network 11" can, for example, depending on its size in relation to the leakage inductance or the rated power of the transformer 10 ", result in a substantial increase in interference voltage or a substantial interference voltage drop.

This is illustrated by FIG. 2, in which the percentage voltage drops for audio-frequency control voltages and for audio-frequency interference voltages on low-voltage transformers as a function of the capacitive load of the associated low-voltage networks are shown very clearly. It shows a coordinate system on whose abscissa 15 the capacitive load N, of a low-voltage network relative to the nominal load N, of the low-voltage transformer and on its ordinate 16 the percentage voltage drop across the low voltage transformer 10, (o / o), are plotted on a suitable scale. The dashed horizontal line 17 represents the ordinate value 1 (= 100%), at which the voltage drop and voltage increase cancel each other out. In the case of a purely ohmic load on a low-voltage network, a relatively small control and interference voltage drop occurs on the low-voltage transformers. This case is shown in FIG. 2 given by the intersection of the ordinate 16 with the function curve 18 .

This voltage drop is initially transformed into an increase in voltage when the same low-voltage network begins to be additionally capacitively loaded, that is to say when in FIG. 2 traces the course of the function 18 from the coordinate intersection to the right. One has a maximum voltage increase when the impedance of the capacitive load equal to the inductive leakage reactance jcoL of the feeding low-voltage transformer. This state is reached at the apex 19 of the function curve 18.

The control voltages of a ripple control transmitter - consisting of the audio frequency generator 21 (FIG. 1), the command device 22, the control contactor 23, the insulating transformer 24, the tuning coil 25 and the coupling capacitor 26 in FIG. 1 - naturally suffer voltage drops similar to the interference voltages on their way from the busbar 8 to the individual receiving devices 12 "'. This is because here only interference voltages are of interest whose frequency is the same or similar to that of the control pulses used.

According to the conditions listed above, the previously known ones had to be used Circuits the minimum sensitivity of the receiving equipment accordingly the greatest possible interference voltage, d. H. corresponding to the greatest possible increase in interference voltage can be set, while at the same time the control voltage on the transmission side by the maximum possible control voltage drop has been determined.

Since at medium interference and control frequencies (around 500 to 1500 Hz) both voltage increases and voltage drops can reach a factor of 5, had to with the previous circuits -with the same and always constant response sensitivity of all recipients - very large tax payments are expended on the sending side.

While it is sufficient at the receiving location that the level of the control pulses is certainly twice as high as the level of the interference voltages, force the above Relationships to the transmission level on the transmission side 5 - 5 - 2, i.e. H. fifty times as high to be chosen as the interference level.

On the other hand, according to the relationships described, those of interest here Interference voltages on their way from the busbar 8 to the individual receivers suffer about the same voltage drops (or voltage increases) as the Control pulses, it is theoretically sufficient if the control level is about twice on the transmitting side is chosen to be as high as the interference level on the transmission side (for example originating from a large rectifier). This, however, only provided that according to the invention the minimum response voltage of the receivers always automatically corresponds to the respective is adapted to the existing interference level. Another requirement for good functioning a ripple control system with the theoretical minimum transmission power listed above is that there are no locally generated interference voltages. With others In other words, the source of the interference voltages must be at least the same from each receiver be as far away as the transmitter.

This is not always true in practice, so that theoretically possible reduction in transmission level (as stated above) practically not always full can be realized.

With reference to FIG. 3 is now to be shown how receiving devices for example can be built, which their responsiveness automatically adapt to the existing interference level. With the terminals 30 and 31 the receiving circuit connected to the low voltage network of, for example, 220 volts, 50 Hz. the Coils 34 and 35 together with the capacitors 32 and 36 form an electrical, two-circuit band filter, which the incoming, for example separates audio-frequency control pulses from the 50 Hz high-voltage current. A voltage dependent one Resistor 33 holds - similar to a surge arrester - surge-like interference voltages away from the actual receiving circuit.

The incoming control pulses are rectified by the rectifier 37 and charged into the storage capacitors 38 and 39. A discharge resistor 42 or 43 is assigned to each storage capacitor. To fulfill the task intended for them, the time constant of the storage capacitor 38 with its discharge resistor 42 is dimensioned much larger than that of the storage capacitor 39 with its discharge resistor 43. The time constant of the capacitor 38 with its resistor 42 should be significantly greater than the duration of a control pulse. On the other hand, the time constant of the storage capacitor 39 with resistor 43 is selected to be of the order of magnitude of the duration of a control pulse. As a result, the storage capacitor 38 is charged much more strongly than the storage capacitor 39 due to the quasi-stationary interference voltages that are always present. If, for example, R42 is chosen to be ten times as large as R43, then interfering voltages lasting over time cause a charging voltage in the storage capacitor 38 that is ten times higher than that in the storage capacitor 39.

On the other hand, short-term control impulses primarily have one Charging of the storage capacitor 39 result. Behave with sufficiently short impulses Namely, the charging voltages U38 to U39 as the capacitance values C38 to C39 Storage capacitors 38 and 39 are now parallel to storage capacitor 39 connected in series with a glow tube 40 and the excitation winding of the remotely operated Relay 41.

If the charging voltage U39 reaches the ignition voltage of the glow tube 40, so the latter ignites. The electrical energy stored in the storage capacitor 39 discharges through the glow tube 40 and the excitation winding of the relay 41. The latter is operated. Its actuation can be further evaluated as required.

The in F i g. 3 shown and just described reception circuit initially has the desired property, that is, its minimum response voltage automatically adapts to the existing interference voltage. This is briefly explained below: Assume first of all the case that the interference voltage at the receiving location is practically zero. In this case, the voltage U38 on the storage capacitor 38 is also zero. If a control pulse now arrives at the terminals 30 and 31 of the receiving circuit, this primarily charges the storage capacitor 39 of the series circuit 38-39 in the manner described above. U39 thereby reaches the ignition voltage of the glow tube 40. This leads to the actuation of the relay 41 in the desired manner. A minimum voltage Ust, "r" of the control pulse at the terminals 30, 31 is sufficient.

On the other hand, if one assumes the case of the quasi-stationary interference voltage At the receiving location, for example, let it be twice as large as the Ustr "t" listed above. This interference voltage - although it is greater than Ust .; "- the relay 41 cannot operate because of their voltage only about a tenth of the storage capacitor 39 benefits. About nine tenths are on the storage capacitor 38, its charging voltage U38 cannot influence the glow tube 40.

But even a control pulse with the minimum voltage Ust """can no longer operate the receiver, because the voltage U38 for the rectifier 37 is a counter voltage which does not allow control voltages less than 2 Ust""for the charging process of the storage capacitor 39 to be effective. Only control voltages in the order of magnitude of 3 Ustms "can sufficiently charge the storage capacitor 39 and cause the glow tube 40 to be ignited with subsequent relay actuation.

The in Fig. 3 shown embodiment for automatic adjustment however, the response voltage of the receiver corresponds to the interference level present in each case nor the inherently undesirable property that the control pulses themselves charge the storage capacitor 38. This sets the response voltage of the receiving device also shifted in the direction of higher control signals. The storage capacitor 38 should ideally only be caused by interference signals and not by control pulses to be charged.

An exemplary embodiment which better meets this requirement is shown in FIG. 4. In this example, three secondary circuits with the coils 35 ', 35 "and 35"' and the capacitors 36 ', 36 "and 36"' connected in parallel are inductively coupled critically to the input circuit of a filter with the capacitor 32 and the coil 34 . The secondary circuit 35 ', 36' are matched to the frequency of the control voltage, the secondary circuits 35 ", 36" and 35 "', 36"' on the other hand, for example, to the lower and upper network harmonics adjacent to the control frequency or to other interference frequencies. In many cases it is sufficient to use only one of the last two circles mentioned. The storage capacitors 38 and 39 are connected in series; Their charges are oppositely directed by the corresponding polarity of the rectifiers 37 'and 37 ", so that in the presence of one or more interference frequencies the ignition voltage of the glow tube 40 is only reached when the difference between the voltages U39-U38 is equal to the said ignition voltage.

The mode of operation of this arrangement is as follows: The secondary circuit 35 ', 36' transmits the interference frequency adjacent to the control frequency only on the edge of its filter characteristic, its amplitude being reduced, for example, to a third compared to the resonance frequency. The secondary circuit 35 ″, 36 ″, on the other hand, is matched to the frequency of the interference signal. If the impedance of the secondary circuit 35 ", 36" with parallel resonance is selected to be only one third as large as the impedance of the secondary circuit 35 ', 36' with parallel resonance, the charging voltage of both storage capacitors 38 and 39 will be the same in the final state. As a result of the smaller parallel resonance impedance of the secondary circuit 35 ", 36", the source resistance of which is only one third compared to that of the secondary circuit 35 ', 36', the capacitor 38 must have three times the capacitance of the capacitor 39 if the time constants of both circuits should be the same. This ensures that the interference signals with the frequencies to which the secondary circuits 35 ", 36", respectively. 35 "', 36"' are matched to charge the two storage capacitors 38 and 39 equally quickly. However, since their charges cancel each other out, changes in the amplitude of these interference signals will not lead to undesired incorrect switching of the receiver.

When receiving control signals, on the other hand, the voltages Ucontrol : Ustör at the output of the secondary circuits 35 ', 36' or 35 ", 36" behave as 9: 1 and taking into account the capacity of the storage capacitor 39, which is a factor of 3 smaller than that of the storage capacitor 38 the charging of the storage capacitor 39 takes place twenty-seven times faster than that of the capacitor 38.

If the frequencies of the interference signals arriving at the receiver extend over a broad frequency band on both sides of the control frequency, a circuit arrangement as shown in FIG. 5, can be provided. This again contains a secondary circuit 35 ′, 36 ′ which is matched to the frequency of the control pulses and which charges the storage capacitor 39.

The secondary circuit 48, 49 in this case represents a resonant circuit with a broad transmission curve, which is connected to a bridge circuit with resistors 45, 46 in one branch and resistor 44 and parallel resonant circuit 50, 51 in the other branch. The parallel resonance circuit 50, 51 is tuned to the control frequency. Resistor 44 is dimensioned so that there is no voltage in one bridge diagonal with storage capacitor 38 and rectifier 37 ″ when the other bridge diagonal is fed with control frequency. All other frequencies which reach the bridge circuit from secondary circuit 48, 49, effect a corresponding charging of the storage capacitor 38 and thus a voltage U38 opposite to the charging voltage U39, as has already been explained in FIG existing filters can also be replaced by cheaper RC elements.

Claims (4)

Claims: 1. Ripple control receiver for networks with changeable Last, characterized in that the level of its response threshold for the control voltage automatically adapting to the level of existing interference voltages and by a security amount is formed lying over her. 2. ripple control receiver according to claim 1, characterized characterized in that to be charged by the signal voltage via a diode (37) Capacitor (39) is preceded by a capacitor (38) and that the time constants both capacitors are set by parallel resistors so that the time constant of the upstream capacitor (38) is larger than that of the other capacitor (39). 3. ripple control receiver according to claim 2, characterized in that the the The capacitor (38), which determines the response threshold, is charged via a diode (37 ") by secondary resonance circuits (35 ", 36", 35 "', 36"') operating on the control frequency neighboring network harmonics are matched. 4. Ripple control receiver according to claim 2, characterized in that the capacitor (38) determining the response threshold lies in the diagonal of a bridge (47), on the other diagonal of which there is a resonance circuit with a wide transmission curve (48, 49), and that the bridge resistances ( 44, 45, 46, 50) are designed so that there is no voltage in the capacitor diagonal when the resonant circuit (48, 49) is excited at the control frequency. Considered publications: German Auslegeschriften Nr. 1071775, 1067084.