DE1285619B - Circuit arrangement for measuring the pulse distortion of pulses generated by a switching component, resulting from a different pulse / pause ratio - Google Patents

Description

The invention relates to a circuit arrangement for measurement the pulse distortion resulting from a different pulse-pause ratio of pulses generated by a switching device using a capacitor, the charging or discharging process of which is initiated by actuation of switching means that switch the switching component on and off synchronously with Switching means are actuated, and it is terminated by actuating switching means, in the same rhythm as a switching element assigned to the switching component are actuated, and its at the end of a pulse or a series of pulses existing residual charge is measured with the correct sign, both with the actuated the switching component on or off switching element synchronously Switching means as well as the switching element, which in the same rhythm as the switching Component associated switching element is actuated, designed as Umschaltkontakimittel are, whose respective counter-contact sides are of the same type, each with a connection end of the Capacitor are connected and the charging current for the Capacitor is fed, and being used to indicate a certain distortion corresponding capacitor charge an evaluation circuit with two upstream Threshold switches are provided, the threshold values of which define the limits, within of which the distortion that has occurred is still permissible.

Arrangements are already known (German patents 910 455, 960 733), which is used to evaluate phase angles between two impulses to the temporal Measure the distance between these impulses with the help of two tubes, each from one the pulses are controlled. This creates a differential voltage at the anodes of the tubes, which is a measure of the phase angle to be determined. These known circuits in particular cannot be used for pulse distortion measurement if the operating voltages required for tubes are not available.

In another known (from German patent specification 742 986) Circuit arrangement is the duration of a relay pulse compared with the duration a control pulse actuating the relay measured by the fact that a capacitor charged from one battery while the relay is on and from another Battery is discharged again during the fall time. The one on the capacitor afterwards remaining voltage is then a measure of the distortion of the relay pulse compared to the control pulse. This known circuit arrangement works with a considerable number of contacts, which is due to the fact that two Batteries must be provided, which in themselves also have a significant impact Represent effort.

In another (from German patent application S 441.09 VIII c / 21e) known circuit arrangement is used to measure or control the average distortions caused by devices serving for impulse transmission of DC control pulses of low pulse train one capacitor during one a certain period of time alternately from the beginning of each original pulse until the beginning of the corresponding, reproduced by the impulse transmission device, distorted pulse and charged from the end of each original pulse Reloaded until the end of the corresponding reproduced pulse. At the end of this Measurement time segment is the size of the pulse distortion assumed by the capacitor Final potential determined. A highly sensitive relay is used for this purpose lies in a comparator circuit in which the comparison with two different Comparison potentials takes place via two rectifiers. These rectifiers are poled so that no current can flow in the relay when the end potential of the Capacitor lies between the two comparison potentials. This means that then in each case a display signal from the known circuit arrangement considered last is output when the respective pulse distortion is outside of a permissible distortion range lies.

The invention is based on the object, while avoiding the one of the disadvantages inherent in the known circuit arrangements previously considered To create a circuit arrangement for pulse distortion measurement, in which a display element responds when the respective measured pulse distortion is within a permissible Range of distortion. This task is performed in a circuit arrangement of the initially mentioned type solved according to the invention in that between the threshold switches and the evaluation circuit bistable multivibrators are connected, of which after occurrence if the distortion is within the permissible distortion, the flip-flop is also included the upstream threshold switch is operated with a lower threshold value, while a non-actuation or an actuation of both flip-flops are considered impermissible Distortion is displayed. This has the advantage that of the invention Circuit arrangement in each case positive "good" signals are emitted, which is reflected in has proven to be particularly useful in many cases, as with the help of a Such signals emitting circuit arrangement also contains errors (e.g. defects in the relevant Circuit arrangement) can be recognized, resulting in a non-actuation of the relevant Lead display organ. An advantage in the circuit arrangement according to the invention in comparison to the known circuit arrangement last considered, it is still that the on the capacitor each after performing a pulse distortion measurement lying voltage only with the threshold voltages of the provided threshold switches is compared without, however, directly as an actuation voltage for the relevant one To be used downstream evaluation unit. To this Way can be advantageous in the circuit arrangement according to the invention Wise elimination of difficulties such as those in addressing the last viewed known circuit arrangement used evaluation relay, if necessary by the Fault current conditions of the relay used there can occur.

According to an advantageous embodiment of the circuit arrangement according to the invention a relay with two windings is used as the indicator, with one Winding is excited by a flip-flop and when both windings are excited the magnetic field cancels. This measure brings the Advantage with itself, that a relatively simply constructed and relatively reliable display element is used is.

It is also advantageous if, in accordance with a further expedient embodiment the circuit arrangement according to the invention, the capacitor with at least approximated constant charging current. As a result, its final voltage is then a direct one proportional measure for the distortion that has occurred in each case.

The invention is illustrated in an exemplary embodiment with the aid of a drawing explained in more detail below.

In the upper part of the drawing, a transmission relay S and a relay A to be examined are shown. The transmission relay S is fed with pulses from a pulse generator IG. In detail, the transmission relay S is connected to a DC voltage source + UI - U during the respective pulse generation by the pulse generator IG .

The transmission relay S has two pulse contacts, namely a normally open contact s 1 and a changeover contact s2. The contact s 1 of the transmitter relay S controls the relay A, which is connected to a DC voltage source + U / - U via this contact s 1. The relay A, which represents the relay to be examined, has a changeover contact a. The idle times of the two changeover contacts s 2 and a are, as shown in the lower part of the drawing, connected to the one assignment of a capacitor C. The working sides of the relevant changeover contacts s 2 and a are connected to the other assignment of the capacitor C. The changeover contact springs of the two changeover contacts s2 and a are connected to a DC voltage source + U / - U via a resistor R 1. In this circuit there is also a break contact p 1, which will be discussed further below.

To measure the pulse distortions caused by the relay A, the transmission relay S is fed by pulses supplied by the pulse generator IG. This transmission relay S is brought to pick up or drop out according to its duration and time interval. During these two states, the relay A to be examined is influenced in the same way by the contact s 1 actuated by the transmitter relay S. If the impulses supplied by the relay A to be examined are distorted compared to the impulse generated by contact 1 or s 2, this distortion manifests itself in a time shift in the actuation of contact s 2 compared to contact a.

When the transmitter relay S is actuated, the contact s2 moves into its working position, while the contact a belonging to the relay A to be examined is initially still in its rest position for the duration of the response time. As a result, the capacitor C is charged, since there is a circuit of + U, resistor R 1, working side of pulse contact s 2, capacitor C, resting side of pulse contact a, break contact p 1, - U. The relay A to be examined is also energized by the contact 1 actuated at the same time, which after its pick-up time switches its contact a to its rest position, whereby the previously described charging circuit for the capacitor C is interrupted. If the transmitter relay S is brought to fall again, the switchover contact s2 belonging to this transmitter relay returns to its rest position, whereas the contact a is still in its working position for the fall time of the relay A. This creates a renewed charging circuit for the capacitor C, on the basis of which it is recharged in the opposite direction until the relay A controlled by the transmitter relay S via the contact 1 has also dropped out. The initial position of the two contacts s 2 and a is thus reached again. The residual charge with a positive or negative sign remaining on the capacitor C can now be evaluated as a measure of the distortion that has occurred. If switching means are used between the switching contact springs of the two pulse contacts s2 and a and the voltage terminals of a DC voltage source, which allow the capacitor C to be charged in a linear voltage curve, for which z. If, for example, a Miller integrator can be used, the residual voltage remaining on the capacitor C is a directly proportional measure of the distortion that has occurred. In the present case, a high-resistance resistor R 1 is used as such a switching means.

With the aid of the arrangement considered above, it is not only possible to measure the degree of distortion of the relay A to be examined during a single pull-in and drop-out, but this arrangement can also be used to measure the degree of distortion during an entire series of pulses. The remaining charge on the capacitor during each pulse supplied by the pulse generator IG adds up according to the number of pulses supplied by the pulse generator IG is dependent. Among other things, this measure also significantly increases the measurement accuracy of the display of the distortion that has occurred.

According to the invention, an evaluation device constructed with electronic means is provided for evaluating the voltage across the capacitor C, which voltage corresponds to a specific degree of distortion. This evaluation device consists essentially of two bistable multivibrators K1 and K2 with upstream threshold switches S1 and S2, the threshold values of which are of different sizes. The evaluation device is put into operation by means of a relay P to be energized by a key T. This takes place in that the break contact p 1 belonging to the relay P and already mentioned above opens and separates the occupancy of the capacitor C from the negative potential - U. By means of a further contact p 2 belonging to the relay P, the other assignment of the capacitor C is applied to the evaluation device. The voltage of the capacitor C available between + U and the input of the evaluation device now reaches the inputs of the threshold switches S1 and S2. Since the threshold switches S1 and S2 have threshold values of different sizes, the capacitor voltage of the capacitor C must be at least high enough to operate at least one flip-flop K1 or K2 that the threshold value of the threshold switch with the lower threshold limit is reached. In the present case, the threshold values of the two threshold value switches S1 and S2 are dimensioned in such a way that the voltage of the capacitor C lying in this range is evaluated as still permissible as a result of a distortion that has occurred. This is because only the flip-flop with the threshold switch connected upstream can be actuated with a low threshold value. If the voltage of the capacitor C is so low that the threshold value of the threshold value switch with the low threshold value is not reached, no flip-flop is actuated; If, on the other hand, the voltage of the capacitor C is so high that the threshold values of both threshold value switches S1 and S2 are reached, both flip-flops are actuated. Failure to operate the flip-flop with the upstream threshold switch low threshold or the operation of both flip-flops is used as a criterion for the fact that either the distortion has not reached the required minimum value or that something in the arrangement is defective or the distortion is too great. A relay Z is provided to display the status of the two flip-flops K1 and K2. This relay Z has two partial windings, one partial winding of this relay being excited by a flip-flop K 1 or K 2. The two windings of the relay Z are connected at one end to a terminal carrying a potential -I- U. Since the relay Z is a differential relay, it can only be excited when the flip-flop is actuated with the threshold value switch connected upstream of the low threshold value. Failure to actuate the two flip-flops K1 and K2 or actuation of the two flip-flops K1 and K2 leads to the relay Z not being energized.

Claims (3)

Claims: 1. Circuit arrangement for measuring the from one different pulse-pause ratio resulting pulse distortion of pulses, generated by a switching component using a capacitor, whose charging or discharging process is initiated by actuating switching means, the synchronous with the switching component on or. disconnecting switching means are actuated, and is terminated by the actuation of switching means in the same rhythm as a switching element assigned to the switching component are actuated, and its at the end of a pulse or a series of pulses existing residual charge is measured with the correct sign, both with the operated the switching component on and off switching element synchronously Switching means as well as the switching element, which in the same rhythm as the switching Component associated switching element is actuated, designed as a changeover contact means are, whose respective counter-contact sides are of the same type, each with a connection end of the Capacitor are connected and the charging current for the Capacitor is fed, and being used to indicate a certain distortion corresponding capacitor circuit an evaluation circuit with two upstream Threshold switches are provided, the threshold values of which define the limits, within of which the distortion that has occurred is still permissible because. characterized by that between the threshold switches (S1, S2) and the evaluation circuit (Z) bistable Flip-flops (K1, K2) are switched, of which after one occurs within the permissible distortion lying distortion the flip-flop (K1 or K2) with the preceding one Threshold switch (S1 or S2) lower threshold value is operated while non-actuation or actuation of both toggle stages (K1, K2) as impermissible Distortion is displayed. 2. Circuit arrangement according to claim 1, characterized in that that a relay (Z) with two windings is used as a display element, each a winding is excited by a flip-flop (K1, K2) and when both are excited Windings cancel the magnetic field. 3. Circuit arrangement according to claim 1 or 2, characterized in that the capacitor (C) with at least approximately constant Charging current is charged so that its final voltage is a directly proportional measure for is the distortion that has occurred.