DE2948352A1 - Signalling system detecting train on track section - has receiver signalling when monitoring current in one rail fails - Google Patents

Abstract

Each section of track has a transmitter associated with it. The transmitters of adjacent track sections are tuned to different frequencies. Each transmitter acts as a current source applying a receiver via a rail in the track section concerned. The presence of a train on the section causes the current in the one rail to be conducted via the train's wheel axles to the other rail so that the receiver ceases to receive current. The transmitter consists of a power source coupled via a transformer to a diode bridge (V12 etc.) with a ceramic capacitor (C4) across its output diagonal. The capacitor is connected to a blocking oscillator with feedback transformer. The system can be used for two-rail and one-rail insulated rail circuits and also in rail circuits with electrical breaks.

Description

Safe track vacancy detection device

The invention relates to a safe track vacancy detection device the preamble of claim 1.

The tracks on railroads are made up of a series of track and switch sections divided. This serves to secure the train operation and to monitor the operational sequence.

They are monitored to see whether they are occupied by vehicles or are free. The track sections are often monitored by track circuits. A track circuit consists of an alternating current source as a transmitter, which has the Rails of a railway track feeds a receiver.

Adjacent track sections are separated by insulating joints. Located If a vehicle is in a track section, its axles make it a low-resistance one Connection established between the running rails. As a result, there is no more electricity in the receiver and the track section is reported as occupied.

There are also audio frequency track circuits for free and occupied messages of track sections on continuously welded tracks. The Insulating joints are replaced by electrical separating joints. The separation of neighboring Track sections are made by choosing different audio frequencies (Hans Dewald: Audio frequency track circuits "from Signal und Draht, 71 (1979), pp. 94-100).

Such audio frequency track circuits, however, require a high level Effort and show no fail-safe behavior.

The task is therefore to provide a safe track vacancy detection device to monitor a track section to create. The object is according to the invention solved by the measures specified in the claims.

The invention is explained in more detail below with reference to drawings.

In Fig. 1, an embodiment of the invention is shown.

A differential track choke D is one through a resistor R3 Diode bridge circuit V1, V2, V3, V4 downstream tet, their outgoing diagonal points lead to a transistor blocking oscillator circuit with feedback transformer. Of the Blocking oscillator circuit consists of a transistor V7, primary windings Ul, V2 and a Bekundänzicklung U3 of a transformer, resistors R4, R5, R6 and a capacitor C1 for negative current feedback. The capacitor C1 is a plate ceramic capacitor with two connections diagonally opposite on each plst floor covering. In the blocking oscillator circuit there is also a Zener diode V5 for limiting of the stream arranged.

The control potential for the blocking oscillator circuit is via the Resistor R3 and the diode bridge circuit formed. Flows through the transistor V7, due to the voltage division of the resistors R4 and R5 in the base circuit, initially a small collector current. This current is used as a feedback winding acting winding U2 in the base circuit of the transistor is quickly enlarged. The height the feedback voltage determines the maximum possible collector current. The resistance R6 is used to limit the collector current. If the maximum value is reached, none will be Voltage induced more in the primary windings Ul and U2 of the transformer and the Transistor V7 switches to the blocking state. This creates a kickback tension opposite polarity. From this this process repeats itself periodically, i.e. the transistor changes periodically between the switching states "On" and "Off" as long as there is an input signal. The signal voltage is thus in a rectangular shape Impulse voltage converted and transferred to the secondary side U3.

In Fig. 1 a circuit arrangement according to the invention is shown, connected to the receiver via an amplifier consisting of a transistor V8, a diode V9 and a resistor R7. The operating voltage UB placed on the amplifier and on the winding U4 of another transformer. Parallel A further capacitor C2 is connected to the winding U4. The winding U5 of the transformer is connected to another plate ceramic capacitor C3 via diodes V10, V11 tied together. The center tap of the winding U5 is with the opposite tile covering of the plate ceramic capacitor C3. From the plate ceramic capacitor C3 the signals are transmitted to an actuator 8t.

Fig. 2 shows the potential-free transmission of the signals to the receiver via a light transmitter LS, via optical fibers L and a light receiver LE a resistor R8 on the actuator.

In Fig. 3, the transmission via copper cable is shown in which no operating current is required in the receiver. The capacitor C2 is used for tuning.

If any fault occurs in the circuit arrangement, e.g. due to component failure, short circuit or interruption, no signal can be sent get the actuator.

If the transistor V 7 fails, the blocking oscillator circuit can not swing out. If one of the capacitors C1 or C3 breaks at any one Place, no signal can reach the actuator either. The same goes for for changes in the resistance values towards zero or towards infinity.

Every possible error (including line interruption) leaves a track occupancy report comes about.

In principle, the track circuits can use direct and alternating current be fed. The receiving circuit enables perfect working with both modes of operation.

Claims (4)

Claims 1. Secure track vacancy detection device for monitoring of a glacial section, characterized in that between a differential track throttle a track circuit and a receiver a diode bridge circuit, a plate ceramic capacitor with two connections arranged diagonally opposite one another on each paving and a blocking oscillator circuit with a feedback transformer are switched on. 2. Safe track vacancy detection device according to claim 1, characterized characterized in that the feedback transmitter is connected to the receiver via an amplifier connected is. 3. Secure track vacancy detection device according to claim 1, characterized in that that the feedback transformer with the receiver via a light transmitter, a fiber optic cable and a light receiver is connected. 4. Safe track vacancy detection device according to claim 1, characterized characterized that the feedback transmitter is connected to the receiver via copper cable, a capacitor and another transformer is connected.