DE2458363B2 - Arrangement for intrinsically safe monitoring of impulse transmission paths - Google Patents

Description

The invention relates to an arrangement for intrinsically safe monitoring of pulse transmission paths.

Impulse transmission paths, their function for the protection of human life or for prevention major damage is important must be monitored. For example, the signal »Free Journey «only become effective after several conditions have been met. These include: the points are in the End position locked and the intersections secured, the "stop" signal in the opposite direction lights up, the section of track to be traveled is unoccupied, etc. The information about this is converted into a series of impulses by means of a detection element. If the set condition is met, pulses are present, if the condition is not met, they are missing Impulses. Each of these pulse series, which represent a fulfilled condition, becomes an input of one Supervision or coincidence chain supplied. The output pulses of the coincidence chain only appear when pulses are present at all inputs, i. H. when all conditions are met. The appearance of impulses at the output of the coincidence chain is evaluated as the "free travel" signal. If an or Several components of the coincidence chain are disturbed or faulty and at least none at one of the inputs If pulses are present, an output pulse may under no circumstances be emitted (intrinsic safety).

A relatively simple intrinsically safe monitoring of the impulse transmission paths is based on that in the Relay technology known principle of quiescent current transmission. There are pulses with a certain frequency transmitted and the disappearance of these impulses represents the alarm signal. that there are no additional pulse sources along the transmission path, the pulse transmission aborted in the case of a defective component.

The relays are kept in an energized state with the input signal. The output signal is delivered via the serially arranged Arbcitskontaktc dev relay. (It is assumed that if the relay fails, the armature will definitely drop out. Special relays are made for these applications.)

In many applications it cannot be expected that in the Transmission paths the impulses appear at the same time. The impulses must therefore be saved. On the other hand, the safe working of the

ίο Coincidence chain can be guaranteed if the input pulses occur at the same instant.

The object of the present invention is to provide a contactless, with the possibility of pulse storage provided, intrinsically safe coincidence chain, in which also in the case of simultaneously occurring Input pulses the monitoring security is guaranteed.

This object is achieved in that a known per se from ferrite cores and Transistors composed coincidence chain is provided that the write winding of the Ferrite core supplied current pulse is wider than that supplied to the reading winding and that the maximum The value of the flow caused by the read pulse is greater than that caused by the write pulse.

The idea on which the invention is based is to be explained in more detail using an exemplary embodiment.

1 shows the structure of a coincidence chain and FIG. 2 shows the structure of an input amplifier connected upstream of the input windings.

The coincidence chain shown in Fig. 1 consists of four ferrotransistor elements 1 to 4, the composed of a transistor and a ferrite core with a rectangular hyteresis loop

■ J5 are. The logical operation (coincidence) is carried out on the ferrite core. The transistor only serves as an amplifier and connection element. Each ferrite core has at least three windings Wl, W2 and W3, the winding Wl being referred to as the write-in, Wl as the read and Wi as the output winding. The output pulse of the first ferrotransistor element 1, which is tapped at the collector of the first transistor, is fed to the read winding W2 of the second ferrotransistor element 2, the output pulse of the second to the read winding Wl of the third ferrotransistor element 3, and so on. The respective monitoring pulses are fed to the write-in windings W1 of the ferrotransistor elements 1 to 4 via the inputs a1 W, a2W, etc. The output of the coincidence chain is given by the output terminals A connected to the collector or emitter of the last transistor. The operation of the individual transistor elements Ferro is as follows: Assuming that the ferrite core in the magnetization state - Bm is, will be implemented over the Einschreibewicklung WI with a current pulse / Ί in the magnetization state -I- Bm. A negative pulse is induced in the output winding Wi. The ferrite core can again via the read winding W2 with a current pulse / 2

^{can be} reset. A positive pulse is thereby induced in the output winding W3, with which a connected npn transistor is opened and the pulse is further transmitted. will.
The safe required in the task

^The work of the coincidence chain, even with input pulses occurring at the same time, is solved by varying the duration of the input pulses and by different flow rates.

The current pulse fed to the write-in winding Wl is wider than that fed to the read-out winding Wl. In addition, the maximum value of the flow caused by the read pulse is twice as large as that of the write pulse.

D'e different widths of write-in pulse and read pulse is achieved by an input amplifier connected upstream of the write-in winding, on which the desired pulse width can be set. By choosing the resistance and the number of turns of the reading winding Wl , twice as large a flow through the reading winding Wl as that of the writing winding can be achieved.

If there are no pulses at one or more inputs, pulses must not appear at the output under any conceivable real circumstances (defect in the chain, etc.) (intrinsic safety). In order to avoid short circuits between the windings attached to the ferrite core, they are designed as Sektoi windings. Since the ohmic resistance of the ferrite core is very high, the windings of the ferrite core do not need to be insulated. In the worst case, an interruption in the winding can cause the existing output impulses to disappear. The permanent magnetic bias of the ferrite core by a defective transistor that could possibly trigger false pulse is avoided in that the Koirizidenzkette is fed via a metered for ·> nominal current. If a transistor in the chain breaks down, the fuse will blow. A series resistor can also be used instead of the fuse. In the event of a transistor breakdown, the working voltage is reduced in the ratio of collector resistance to series resistance so that no output pulse can be emitted.

The input amplifier shown in FIG. 2 and connected upstream of each input winding Wi and the reading winding Wl of the first ferrotransistor element 1 essentially contains a field effect transistor and an npn transistor. An amplified pulse / (t) is emitted when the input signal u _ä (t) changes. The desired pulse width is set with the capacitor Cm located in the base line of the npn transistor. So that of the reading winding Wl of the first ferrotransistor! half as wide as the pulse fed to the input windings Wl of the ferrotransistor elements 1 to 4.

1 sheet of drawings

Claims (3)

1 claims: 1. Arrangement for intrinsically safe monitoring of pulse transmission paths, characterized in that a known per se composed of ferrite cores and transistors coincidence chain is provided that the write winding (Wi) of the ferrite core supplied current pulse is wider than that supplied to the reading winding (W2) and that the The maximum value of the flow caused by the read pulse is greater than that caused by the write pulse. 2. Arrangement according to claim 1, characterized in that all the write-in windings (WX) and the read-out winding (W2) of the first FeiTotransistorelementes (1) composed of ferrite core {la) and transistor ( 1b) are preceded by input amplifiers on which the pulse width is adjustable . 3. Arrangement according to claim 1, characterized in that the supply voltage of the coincidence chain is applied via a series resistor or a fuse.