DE1205145B - Circuit arrangement for monitoring the amplitude of electrical alternating quantities, in particular of track voltages in railway safety systems - Google Patents

Description

Circuit arrangement for monitoring the amplitude of alternating electrical variables, in particular of track voltages in railway safety systems The invention relates to a circuit arrangement for monitoring the amplitude of alternating electrical variables, in particular of track voltages in railway safety systems, using magnetic storage cores with an almost rectangular hysteresis loop. The inventive circuit arrangement is particularly suitable for installations where the required for supplying the AC voltage rails and a required for the circuit power supply will not be taken from a common feed source.

Such circuit arrangements are used, for example, for railway safety systems required, in which isolated track sections are provided for track monitoring, the rails of which are fed with an alternating voltage at one end. At the other The end of the rails is a track relay, e.g. B. an electronic circuit arrangement in connection with a relay, provided that the voltage between the rails, the so-called track voltage, monitored. The track relay is when the track is free and current track voltage is attracted and drops when when occupying the assigned Track section the rails are short-circuited by a vehicle and the track voltage thereby reaching the value zero.

In many cases, however, the vehicles do not form an ideal short circuit, so that the track voltage is not completely reduced to the value 0 . In these cases, a certain residual tension remains between the rails, which in the worst case differs only slightly from the track tension when the track section is not occupied. For this reason, the track relay must be designed in such a way that it can reliably issue a criterion about the respective track condition in these cases as well. This requires a decay factor of approximately the value 1, which is not achieved by previously known relays. As a waste factor z. B. denotes the ratio of dropout voltage to response voltage of the track relay in question.

A circuit arrangement with a pre-magnetized toroidal core with a square-wave hysteresis loop and a downstream relay can be used as a track relay with a high drop-out factor. All half-waves of the track voltage that are opposite and greater than a threshold value specified by the premagnetization and the coercive force of the toroidal core re-magnetize the toroidal core. The control voltage generated in an output winding of the toroidal core during this process or during reverse magnetization causes the downstream relay to be attracted. If the value falls below the specified threshold value as a result of the track being occupied by vehicles, the toroidal core is not magnetized and the relay drops out. The premagnetization in such a circuit arrangement can be derived from a comparison voltage proportional to the AC supply voltage of the track. This has the advantage that the track relay reliably reports the respective track status - occupied, not occupied - regardless of possible fluctuations in the AC supply voltage of the track, because the magnitude of the premagnetization is always in a fixed ratio. to the AC supply voltage. The prerequisite for this is that a separate feed line, which is not loaded by consumers, is provided between a source emitting the alternating feed voltage or the feed point of the track, which transmits at least the comparison voltage to the respective track relay. However, the separate lines represent an increased, undesirable expense.

In practice, either a separate battery is required for the track relay provided, which provides the necessary supply voltage, or the track relay together with other consumers, such as point machines etc., is due to the general Supply network that also provides the alternating voltage for the tracks. In both In some cases it is not possible to provide the track relay with a supply voltage to that is in a fixed ratio to the AC supply voltage of the track. If this is the supply voltage and thus the comparison voltage of the track relay drops, the toroid is no longer premagnetized so strongly, so that the Remagnetize the toroid with residual voltage when the track is occupied and thus a Can trigger track vacancy detection. This possible hazardous condition must be eliminated.

The invention is based on the object of avoiding these disadvantages and to create a circuit arrangement for monitoring the amplitude of the alternating quantity, which does without the equivalent voltage and also has a good decay factor Has.

To achieve this object, a circuit arrangement is suitable according to the invention in which two memory cores are provided, each with a control winding acted upon by the alternating variable and are dimensioned so that the first memory core when a lower predetermined value of one direction of the alternating variable is exceeded than the second memory core from a first The remanence position can be converted into the other remanence position, which is provided when it is magnetized back into the first remanence position in the other direction of the alternating variable from an output winding to re-magnetize the second memory core and the pulse output from its output winding to control a downstream signaling device.

The subject matter of the invention and expedient additions are explained in more detail below using an exemplary embodiment. In the drawing, Fig. 1 shows a circuit arrangement for monitoring the amplitude of an alternating voltage, Fig. 2 different diagram lines with the alternating voltage to be monitored and pulses in different lines as well as the switching status of a relay contained in the circuit arrangement.

In Fig. 1 , the alternating voltage W to be monitored is fed to a transformer T. This transformer T controls two toroidal cores 1 and 2 with an almost rectangular hysteresis loop with the aid of a secondary winding S. Various magnetization windings 11 to 13 are applied to the toroidal core 1 and the windings 21 to 23 are applied to the toroidal core 2. The control windings 11 and 21 are connected in series to the secondary winding S of the transformer T via a capacitor C. As a result, this circuit is matched to the frequency of the alternating voltage to be monitored. This has the advantage that the control power required to control the two toroidal cores 1 and 2 is significantly reduced compared to the power for a non-coordinated circuit. The first toroidal core 1 is dimensioned in connection with the control winding 11 , for. B. by appropriate choice of cross-section, diameter and material of the core as well as the number of turns of the winding, that it is already when a low predetermined value Xl of the alternating voltage W or the oscillating circuit current is exceeded in the positive direction A from a first remanence position "1" in the other remanence position »0« is remagnetized. The second ring pin 2, however, in connection with the control winding 21, enables the magnetization to be reversed from the remanence position "1" to the remanence position "0" or vice versa only at a given higher value X2 of the resonant circuit current. The toroidal core 1 is therefore already remagnetized at very small amplitudes of the resonant circuit current. When the toroidal core 1 is magnetized back into the remanence position "1" by a negative half-wave of the resonant circuit current running in the opposite direction to A , a voltage is induced in the output winding 13 , which turns an assigned transistor T 1 into conductive state with a pulse on the line B. As a result, a current flows through the feedback winding 12, which supports the re-magnetization of the ring core 1 and causes the re-magnetization of the ring core 2 with the help of the magnetization winding 22 in the remanence position "1" . This ensures that the toroidal core2 is definitely in the remanence position "1" as a result of a defined pulse after every negative half-wave of the oscillating circuit current or the alternating voltage to be monitored, i.e. even if the amplitude is below the specified value X2. Therefore the toroidal core 2 cannot be magnetized step by step from the remanence position "1" into the remanence position "0" by a number of amplitudes of positive half-waves lying below the predetermined value X2.

A transistor T2 is connected to the output winding 23 of the toroidal core 2, which is switched on when the toroidal core 2 is magnetized back from the remanence position "0" to the remanence position "1" by the pulse occurring in the line C. The transistor T2 emits a current pulse for controlling downstream devices via its switching path.

To lengthen the current pulses, a pulse lengthening circuit with a toroidal core 3, on which magnetic., Netization windings 31 to 33 are arranged. With the help of the magnetization winding 31 , the toroidal core is premagnetized up to a saturation position. The magnetizing winding 32 is acted upon by the current pulses of the transistor T2. Here, the toroidal core briefly moves from the position specified by the premagnetization to the other position. After the current pulse has ceased, the toroidal core returns to the first position as a result of the premagnetization. In this case, a voltage is induced in the base winding 33 , which switches a downstream switching transistor T3 conductive, so that a relay L connected to its switching path is excited and picks up. Pulling in the relay L is then a sign that the specified value X2 of the alternating voltage to be monitored has been reached or exceeded. The lengthening of the current pulse comes about because the remagnetization of the toroidal core 3 into the first position takes longer than the remagnetization from the first position (saturation position) to the other as a result of the counteracting action from the winding 33 in connection with the control circuit of the switching transistor T3 Location.

F i g. 2 shows various diagram lines with pulses present on lines B and C as a function of the alternating voltage W to be monitored, as well as the switching state of relay L. It is assumed that the amplitudes of the first four half-waves of the alternating voltage to be monitored are below and the amplitudes of the the following three half-waves are above the specified value X2. In the case of all negative half-waves, the voltage induced in the output winding 13 of the toroidal core 1 generates a pulse on the line B, which controls the transistor T1 to be conductive. However, since the toroidal core 2 is only in the remanence position "0" after the third and fourth positive half-cycle, it is only when it is magnetized back into the remanence position "1" through the current through the switching path of the transistor T1 in the third and fourth negative half cycle on each line C an output pulse that switches the transistor T2 conductive. After the first output pulse on the line C has ceased, the relay L is excited by a current through the switching path of the switching transistor T3.

The embodiment described shows that a circuit arrangement according to the invention avoids the disadvantages mentioned in the introduction to the description, since the predetermined value X 2 for the core 2 is not dependent on a premagnetization of this core. The premagnetization provided for the pulse extender circuit is always in a fixed ratio to the counter magnetization with the aid of the transistor T2. Thus, even in the event of fluctuations in the supply voltage feeding the circuit arrangement, it cannot falsify the evaluation. Another advantage is that it is not possible to remagnetize the toroidal core 2 step-by-step, since it is returned to a defined starting position, namely to the remanence position "1", in every negative half-wave of the alternating voltage to be monitored. In addition, the output pulse on the line C is not dependent on the curve shape of the current flowing through the winding 21, because the toroidal core 2, which is in the remanence position "0" for a long time in the case of a positive half-wave of the resonant circuit current, is controlled in the following negative half-wave by a short , defined pulse of the transistor Tl is controlled back into the remanence position "l".

By using a toroidal core 2 made of a material with a good rectangular shape of the hysteresis loop and properties that are as temperature-independent as possible, it is possible to achieve a decay factor that is above 0.9 . This value is no longer reduced in the event of fluctuations in the operating temperature, the supply voltage or the tolerances of the components within specified limits.

The invention is not limited to the illustrated embodiment. For example, other pulse stretcher circuits can also be used.

Claims (2)

Claims-1. Circuit arrangement for monitoring the amplitude of electrical alternating quantities, in particular of track voltages in railway safety systems, using magnetic storage cores with an almost rectangular hysteresis loop, characterized in that two storage cores (1 and 2) each with a control winding (11 or 21) to which the alternating quantity acts. and are dimensioned in such a way that the first memory core (1) moves from a first remanence position ("1") to the other remanence position ("0") when a lower predetermined value of the one direction (A) of the alternating variable is exceeded than the second memory core (2) «) Can be reversed , the impulse (on line B) emitted by an output winding (13 ) to reverse magnetize the second storage core (2) and the one of its Output winding (23) emitted pulse (on line C) for controlling a downstream en reporting device (L) is provided. 2. Circuit arrangement according to claim 1, characterized in that the control windings (11, 21) of the memory cores (1, 2) lie in series in an oscillating circuit (C, S, 11, 21) tuned to the frequency of the alternating variable. 3. Circuit arrangement according to claim 1 or 2, characterized in that to lengthen the output pulses (C) of the second memory core (2) an up to a saturation position pre-magnetized toroidal core (3) with a rectangular hysteresis loop is provided, which can be magnetized by each output pulse against the pre-magnetization is and, after the respective output pulse is canceled during reverse magnetization, controls a switching transistor (T3) via a winding (33) , to the switching path of which a relay (L) is connected.