DE1263810B - Circuit arrangement with a premagnetized toroidal core - Google Patents

Description

Circuit arrangement with a premagnetized toroidal core The invention relates to a circuit arrangement with a premagnetized toroidal core as an amplitude discriminator for an alternating voltage, in particular track voltage for track monitoring in railway safety.

In many areas of electrical engineering relays are required that have the best possible waste factor. Referred to as the dropout factor of a relay the ratio of the dropout value to the pickup value, e.g. B. the ratio of waste stream to response current, electromagnetically operated arrangements. A good waste factor has almost the value »1«. However, many solenoid operated arrangements have only a waste factor on the order of 0.5. This value is quite right Well; however, it can only be achieved through considerable economic expenditure will.

The invention is based on the object with electronic components to build a circuit that has a significantly better decay factor than the known arrangements and also an alternating voltage according to their amplitude evaluates. According to the invention, this object is achieved in that the when exceeded a limit value set by a bias winding by a of the alternating voltage determined counter magnetization of the toroidal core via a Output pulses emitted from the output winding via a rectifier or the like. And another premagnetized toroidal core whose premagnetization winding is in Series is connected to that of the first toroidal core, a signaling device are fed.

An embodiment of the invention is shown below with reference to the Drawing with the F i g. 1 and 2 together with further features of the invention explained.

F i g. 1 shows a circuit arrangement according to the invention with a premagnetized toroidal core K1 that monitors the amplitude of an alternating voltage Um and another toroidal core K2 that monitors the premagnetization of the first toroidal core K1 and a power stage with the toroidal core K3 connected to this toroidal core K2. All toroidal cores have an almost rectangular hysteresis loop. Windings 10 to 13 are arranged on the toroidal core K1. The windings of the toroidal cores K 2 and K 3 are denoted by 21 to 24 and 31 to 35, respectively. The alternating voltage Um, which is to be monitored for its amplitude, is fed to the winding 10 via a decoupling transformer Tr 1. The windings 11, 21 and 31 of the toroidal cores K1, K2 and K3 are connected in series to a DC voltage and generate the premagnetization for the associated toroidal cores. The winding 12 is in the base-emitter circuit and the winding 13 in the emitter-collector circuit T1. Correspondingly, the windings 22 and 23 of the toroidal core K2 are connected to the electrodes of the transistor T2. In series with the winding 23 of the toroidal core K2 is the winding 35 of the toroidal core K3 of the power stage. The power stage is necessary in order to amplify the small pulse powers customary in toroidal core transistor technology to such an extent that they can sufficiently excite a normal, electromagnetically controlled relay. The winding 32 or 33 is connected to the base of the transistor T31 or T32 . The feedback winding 34 is located in the collector circuit of the transistor T 32. The collector circuits of the two transistors T31 and T32 are each connected to voltage via one end of the primary winding of the transformer Tr2, which is provided with a tap. A relay M is connected as a signaling device to the secondary winding of the transformer Tr2 via a rectifier arrangement G.

The mode of operation of this circuit arrangement is illustrated in FIG. 2 explained.

F i g. 2 shows the idealized hysteresis loop f (5) of the toroidal core K 1. The direct current flowing in the winding 11 generates a premagnetization flux ev in the toroidal core K1. An alternating current flows through the winding 10 which is proportional to the alternating voltage Um to be monitored. This current generates the alternating flow O m, which is superimposed on the premagnetization flow 0 v. If the alternating flux O ni sufficiently outweighs the premagnetization flux O v, the toroidal core K1 is remagnetized in the rhythm of the frequency of the alternating flux O m from a remanence position "1" determined by the bias magnetization to the other remanence position "0". Each time the magnetization is reversed, a voltage arises in the winding 12 of the toroidal core K1, which switches the emitter-collector path of the transistor T1 to a low resistance, so that a current pulse flows each time through the windings 13 and 24 =. The winding 13 supports, while the magnetization effect of the winding 10, namely to control the other remanence state "0" the toroidal K1. The current pulses through the winding 24 magnetize the toroidal core K 2 against its premagnetization through the winding 21. This toroidal core also passes from a remanence position "1" determined by the premagnetization into the other remanence position "0" and when the current through the winding 24 ceases as a result of the premagnetization back to the remanence position »1«. With each transition from one remanence position “1” to the other remanence position “0”, a current arises in the collector circuit of transistor T 2, which magnetizes toroidal core K3 of the power stage via winding 35 in the direction opposite to that of the premagnetization flow. This also controls the toroidal core K3 from one remanence position "1" to the other remanence position "0" and, after the current has stopped, back to the first remanence position "1". By changing the magnetization in one direction and the other, the transistor T32 and the transistor T31 are alternately controlled into the current-permeable state. The collector currents of these transistors flow through the part of the primary winding of the transformer Tr2 that is arranged on them. This transformer mainly fulfills the task of isolating the relay M in terms of direct current from the transistors T31 and T32 so that it does not remain constantly energized in the event of a breakdown of one of these transistors. The alternating current occurring in the secondary winding is rectified with the aid of the rectifier arrangement G and excites the relay M, which can have any decay factor.

The feedback windings 13, 23 and 34 contained in the collector circuits of the transistors T 1, T 2 and T32 and arranged on the corresponding toroidal core serve to amplify and fully carry out a magnetic reversal process once it has been initiated. No feedback winding is provided in the collector circuit of transistor T31. This prevents the power stage from becoming unstable and oscillating.

If the alternating voltage Um falls below a certain value, the toroidal core K1 is no longer remagnetized by the corresponding alternating flow of 0 m. The toroidal core K 1 thus remains in the remanence position determined by the premagnetization flow. As a result, no more current pulses arise in the collector circuit of transistor T1. As a result, the relay M iiis secondary circuit of the transformer Tr2 falls after z. B. a period of the alternating voltage.

The magnitude of the alternating voltage Um, at which the toroidal core K1 via its winding 13, the transistor T1 either just emits no pulses or just emits pulses, is determined by a point on the hysteresis loop of the toroidal core K 1. It is assumed here that the hysteresis loop has the idealized rectangular shape shown. Since the "hysteresis loops" are mostly not exactly rectangular, there is a certain area in which the alternating flow rate O m can change without the toroidal core K 1 being completely magnetized and therefore not delivering a definite pulse. In order to obtain as precise a marking as possible of the point at which the ringers are completely magnetized, the feedback winding 13 is arranged in the collector circuit of the transistor T1. As soon as the toroidal core K1 is magnetized from one remanence position into the other remanence position, this remagnetization process is amplified many times over by the transistor T 1 and carried out completely in a short time. This ensures that the toroidal core K 1 or the associated transistor T 1 begins to emit pulses exactly at the limit value set by the premagnetization winding, i.e. at a certain amplitude of the alternating voltage Um , and does not emit any pulses when this amplitude is the slightest undershoot.

The relay M only receives a sufficient current to respond if, for. B. a pulse is emitted to the winding 35 continuously at the interval of one period of the alternating voltage Um from the transistor T2. This defines a period of time in which the amplitude of the alternating voltage changes. can without the relay responding. It is calculated from the frequency of the alternating voltage Um to be monitored. At a frequency of 100 Hz, for example, a corresponding change in the amplitude of the alternating voltage can be evaluated by the relay M after 10 milliseconds at the latest, because after this period a pulse must be given to the winding 35 again if the relay M is not to drop out.

As in this circuit arrangement for the ini secondary circuit of the transformer Tr2 lying relay M so there are two exact criteria, namely either current or no current as a function of a value of the amplitude of the alternating voltage Around; it is completely irrelevant which decay factor the relay M has. Through this has the entire circuit arrangement including the power stage and the relay the waste factor »1«.

In addition to the two windings 13 and 24, there is a resistor-capacitor circuit R1, R2, C in the collector circuit of transistor T 1 AC voltage Um has risen to such an extent that the capacitor C can supply just the energy required to remagnetize the toroidal core K2 when the output pulse is emitted via the transistor T1. The resistor R1 is selected to have a low resistance to the resistor R 2 and is used to limit the current for the transistor T1. With this circuit, the entire circuit arrangement is insensitive to interference voltages with a frequency which is higher in relation to the frequency of the alternating voltage Um to be monitored. It can be expedient to also provide such a resistor-capacitor circuit in the collector circuit of the transistor T2 in order not to allow an excessively large current to flow in the event of a short circuit or breakdown of this transistor. The main task of the toroidal core K2 is to monitor the premagnetization of the toroidal cores. If, for example, the premagnetization fails due to a line break, any value of the amplitude of the alternating voltage Um could trigger pulses in transistor T1. However, these cannot continuously remagnetize the ring K2, since it remains in a certain remanence position after the first pulse due to the lack of pre-magnetization. As a result, no pulses are given to the winding 35 of the power stage, so that the relay M drops out or remains dropped out.

It is favorable to the pre-magnetization flow for the toroidal core K2 to be dimensioned in such a way that it just brings it into the area of saturation. In this way, the toroidal core K2 can even with a slight reduction in the premagnetization flow are no longer remagnetized and thus no voltage pulses generate more in the winding 22.

It is possible, if you do without the stage with the toroidal core K2, the Monitoring of the premagnetization of the toroidal core K1 with the toroidal core K3 of the power stage perform. The pulses emitted by the transistor T1 would then have to be the Apply to winding 35, which is followed by the resistor-capacitor circuit were.

The invention is not limited to the illustrated embodiment. It is also possible to use the power stage with just one transistor, e.g. B. the transistor T32 to build. In this case, the change indicated by dashed lines in FIG. 1 applies. In order to use this power level as completely as possible and with good efficiency, are the bias current flowing through the lower part of the primary winding and the pulse current flowing through the upper part is dimensioned in such a way that the secondary winding of the transformer Tr2 the highest possible alternating current power can be drawn can.

Claims (4)

Claims: 1. Circuit arrangement with a pre-magnetized toroidal core as an amplitude discriminator for an alternating voltage, in particular track voltage for track monitoring in railway security, characterized in that when a limit value set by a pre-magnetization winding (11) is exceeded by a counter magnetization determined by the alternating voltage (Um) of output pulses delivered to the toroidal core (K1) via an output winding (12) via a rectifier or the like (T1) and a further premagnetized toroidal core (K2), the premagnetization winding (21) of which is connected in series with that of the first toroidal core (K1), a reporting device (M) are fed. 2. Circuit arrangement according to claim 1, characterized in that the with the premagnetization winding (11) of the first toroidal core (K 1) series-connected bias winding (21) of the second toroidal core (K 2) such a flow in the direction of a remanence position produces that this toroidal core is brought straight into the area of saturation and that the output pulses emitted by the first toroidal core (K1) make another winding (24) of the second toroidal core (K2) for magnetizing in the direction of the other remanence position Food. 3. Circuit arrangement according to claim 1, characterized in that at least the amplifier (transistor T 1) provided for amplifying the output pulses of the first ring core is connected to a supply current source via a resistor-capacitor circuit (R1, R2, C) which is dimensioned in this way is that the capacitor voltage is only sufficient after approximately one full period of the alternating voltage to be monitored (Um) to allow an output pulse to flow with the current intensity required to reverse the magnetization of the subsequent ring learning (K2). 4. Circuit arrangement according to claim 1, characterized in that a relay (M) with any waste factor is used as the signaling device, which is connected via a rectifier circuit (G) to the secondary winding of a transformer (Tr2), on whose primary winding with center feed the collectors of two transistors (T31, T32) connected against each other are connected directly or indirectly, of which the first (T 31) is connected only to the base, the second (T32) to the base and collector to the windings of a premagnetized toroidal core (K3) .