DE1530415B1 - Circuit arrangement for monitoring light signals, in particular light signals fed by alternating current, in railway safety systems - Google Patents

Description

The invention relates to a circuit arrangement for monitoring Light signals, in particular from light signals fed by alternating current, in railway safety systems with several separately connectable light signal circuits in each light signal circuit Monitoring switching means are assigned, which are dependent on the sizes of the in the switched on light signal circuits, currents flowing normal operating conditions of the relevant light signals or faults in their circuits.

The monitoring of the light signals in the railway safety systems high security requirements are set in order to avoid endangering caused by disturbance Recognize signal patterns in good time and avoid them. In no case are allowed through Such disturbances signal aspects appear or a halting element without corresponding Put the display on the table in the signal box to go out. These disturbances will especially with large distances and corresponding cable cross-sections brought about by wire contact or by the incidence of external voltage. Continue to be variable operating voltages are used to feed the signal lamps to a Avoid dazzling drivers in the dark. Even the operational ones different distances between the feed point and the signal point taken into account when monitoring the light signals depending on the signal current fed in will. At the feed point, which in most cases is in the relay room of the Interlocking is located, by means of monitoring switching means, which are in the corresponding Signal circuits are arranged, the dependencies of the signal states in the Transfer the rest of the interlocking system.

When taking advantage of the largest used in railway safety systems Conductor cross-section results in a certain for the maximum power to be transmitted Distance of the light signals. Large distances result in one substantial high line resistance of the feed line, which is necessary for the detection of Disturbances, especially at the signal location and on the lines, complex monitoring switching means makes necessary, since this is the operating currents and those caused by disturbances Currents can be close together. For these reasons one has gone over to around line contact, external voltage incursions into the feed line and high residual currents determine the light signal circuits in the event of a signal lamp failure, the signal circuits to be monitored by suitable electronic switching means.

In a proposed monitoring device for alternating current circuits of the light signals in railway systems with variable operating voltages, in which, depending on the operating current, faults in the light signal circuits are displayed via current transformers, monitoring devices are provided for this reason in which the voltage occurring at the secondary winding of a current transformer with normal operating current in Dependence on an anti-phase partial voltage derived from the operating voltage is almost compensated. A half-wave of this differential voltage is fed via further switching means to a transistor, in whose collector circuit the display switching means is arranged. In another known monitoring device for alternating current circuits with variable operating voltage (German patent specification 1131256) , two transformers with highly permeable cores are used to monitor a signal circuit for the upper limits of the primary current, the primary winding of one current transformer being connected in series with the primary winding of the other transformer and its secondary windings are switched against each other.

The ratio of the number of turns and / or the core cross sections of the two transducers is dimensioned so that the permeability maximum is approximately reached in No of the first converter when the No of the second converter used by the permeability increase. The differential voltage generated at the two secondary windings is fed to several electronic switching means, which in turn act on a display element.

These known devices are very expensive, and especially the the latter requires precise and difficult adjustment of the transducers. Furthermore With these known monitoring devices, disturbances in the signal circuit can occur can be recorded, but no statements can be made about the type of disturbance. The use of electronic switching means in the known monitoring devices require further additional circuits, has the further disadvantage that by the large number of components reduces their operational reliability.

The invention is based on the object of a circuitry simple and economical circuit arrangement for monitoring light signals to create that avoids the disadvantages of the known monitoring devices.

This Aufcrabe is achieved according to the invention in that parts of the Monitoring switching means for at least two light signals that are not switched on at the same time are arranged combined in such a way in the relevant light signal circuits that due to the dimensioning of the switching element parts, one monitoring switching element in each case over a certain light signal circuit at normal operating current and over the other light signal circuit only responds when the maximum operating current exceeded by a certain amount in this circuit as a result of interference will.

Due to the arrangement according to the invention, in the simplest case, commercially available relays can be used instead of special transformers with highly permeable core sheets and electronic components such as diodes and transistors. In the further embodiment of the invention, parts of the monitoring switching means of a light signal circuit are arranged in a plurality of light signal circuits in order to display faults. If the security of the monitoring of the light signal circuits is to be increased, in particular against the incursion of external voltage into the feed lines of the light signals, then, according to a further development of the invention , a part of already existing monitoring switching means of further light signal circuits is arranged in each of the two feed lines of a light signal circuit in order to display malfunctions.

In special cases, such as B. when there are only two signal circuits, whose two light signals are connected via a three-wire feed line are, is part of the intended to display the disturbances in the light signal circuit Monitoring switching means in the dependency circuits of the signal setting relay arranged.

Embodiments of the invention are shown in the drawing and are described in more detail below. Only the circuit parts are shown in the drawing which are absolutely necessary for understanding the invention.

In Fig. 1 , two light signal circuits 1 and II are shown, in which two light signals (light signal terms) that cannot be switched on at the same time during operation are switched on by means of alternating current via lines 1 to 4 and transformers T 1 and T2. Furthermore, the dependency of the circuits are illustrated by its windings S I and S 11 S signal actuating the relay to the contacts S 1 to S 3 and indicated a StörmelderelaisM with the KontaktM1. To monitor the normal operating currents or disturbances in the two light signal circuits 1 and II, two monitoring switching means, namely the relays A and B with their transformers Tr 1 and Tr 2 consisting, for example, of three windings 11 to 13 and 21 to 23 , are provided.

In the light signal circuit I, the winding 11 of the connected transformer Tr 1 and the winding 23 of the transformer Tr2 connected in series and the voltage leading supply line 2, is fed at a consumer the signal light L 1 through the transformer T 1 and may represent the signal aspect.

In the light signal circuit II, the winding 21 of the transformer Tr2 and the winding 13 of the transformer Trl are connected in series to the feed line 4, which is only energized after the actuating process has been initiated and to which the signal lamp L2 is connected as a consumer via the transformer T2. The lamp L 2 is switched on via the feed lines 3 and 4 after a switch-on button has been pressed; Contact ET is switched over, and after the relay S has responded via winding S I (circuit: battery =, contacts Bl, ET, MI, winding SI and battery-), contacts SI to S3 are switched over .

If there is no fault, normal operating current flows in the light signal circuit 11 , the magnitude of which is between certain amounts, depending on whether day or night voltage is applied. The winding .gen 21 and 22 of the transformer Tr 2 are designed so that the relay B with minimal operating current, d. H. normal operating current at night voltage, picks up and moves its contacts B 1 and B 2. Simultaneously with the response of the relay B, the relay A is de-energized, since the light signal circuit 1 is interrupted by the contact S2. The contacts A 1 and A 2 are thus switched over, and the relay M, which is provided with a slight drop-out delay, remains energized again via the folded contacts A 2 and B 2, and the relay S now holds itself via the folded contacts B 1, S 1, A 1 and its winding S II in a self-closing circuit. The switch-on button with the ET contact can now also be released. The KontaktAT of a cancel button is used to switch off the signal lamp L2 in special cases.

The winding 13 of the transformer Tr 1 is dimensioned depending on the relay A and the winding 12 so that in the event of a fault, for. B. in the event of a short circuit between lines 3 and 4 of the light signal circuit II due to the excessive current the relay A attracts and its contacts A 1 and A 2 in the F i g. 1 assume the position shown. As a result, the circuit of relay M is interrupted by contact A 2 and the self- circuiting circuit of signal control relay S is interrupted by contact A 1 , so that on the one hand, the dropped relay M transmits a fault message to the interlocking circuit and, on the other hand, the light signal circuit 1 is switched on again through contact S2 will. The light of the lamp L 1 shows , for example, the signal term “stop”.

In this position, let the circuit arrangement of FIG. 1 in basic position. The light signal circuit 1 is switched on, and when the operating current is normal, the lamp Ll lights up, and the monitoring switching means relay A picks up, since the windings 11 and 12 of the transformer Trl are designed for this operating current. Furthermore, the circuit of the relay M with the contacts A 2 and B 2 is excited and the relay M is attracted. By means of contacts (not shown) of the relays A and M that are attracted, the correct signal aspect is displayed in the interlocking circuit with a lit lamp L 1 . If the filament of the lamp Ll is destroyed, the secondary circuit of the transformer Tl is de-energized. However, a residual current still flows through the primary circuit of Tl, at which, however, the relay A will definitely drop out. It opens the circuit of the relay M with its contact A 2. RelaisM drops reports by dependence in the absence of the Fallen relay A z. B. that the lampLl is burned out, and prevents the connection of the signal circuit 11 at the same time, for example by contactM1.

In the event of wire contact between lines 1 and 2 or in the event of a corresponding external voltage incident in these wires, the current flowing into the light signal circuit 1 rises above the maximum operating current. Relay A remains energized, and relay B is now also energized via the appropriately dimensioned windings 23 and 22 of the transformer Tr2 and interrupts the circuit of relay M with its contact B 2. Relay M drops out and does not report together with the energized relay A via The illustrated circuits show the contact between the cores and the external voltage in the light signal circuit 1 to the interlocking system.

The normal operating status or the same faults in the light signal circuit 11 are displayed in the same way, only the functions of the relays A and B are interchanged.

The functionality of the relay B or A for displaying the faults is checked in each case in the light signal circuit in which the relevant relay is used to display the normal operating current.

In the case of the FIG. 1, for example, as an AC-powered light signal circuits, commercially available AC relays can be used for the monitoring switching means and commercially available core material for the transformers, the dimensions of the parts being optimally designed for their intended use in a manner known per se.

In the case of simple alternating current fed light signal circuits and light signal circuits that are operated with direct voltage, e.g. B. with light signals with a relatively small digit distance, the monitoring switching means z. B. only consist of relays. In this case, the relays are provided with two or more windings, which are dimensioned accordingly in the same way as the transformer windings according to FIG . 1 can be arranged in the various light signal circuits.

In Fig. 2 three light signal circuits I, II, III are shown, which feed the signal lamps L 1 to L3 via the lines 1 to 6 and the transformers T 1 to T 3. Contacts S2 to S4 of signal relay (not shown) are arranged to switch on the light signal circuits. The relays A, B, C with the transmitters Trl to Tr3, for example, are provided as monitoring switching means for these light signal circuits. The windings 11 to 14 or 21 to 23 and 31 to 33 are assigned to these transmissions. The transfer windings are dimensioned in the same way as in FIG. 1 described. Likewise, the relay A, B, C with their contacts (not shown) act on the dependency circuits in the signal box.

In Fig. 2, the circuit arrangement of the light signal circuit I is designed, for example, so that the interference voltage in both lines 1 and 2 can be detected with certainty. In the event of a fault, the following can be used: contact between lines 1 and 2, external voltage in line 2, as well as voltage in its own phase and external phase in line 1, in each of the feed lines e.g. B. the circuit I each have a winding 23 or 33 of the transformer Tr2 or Tr3 of the switching means already available for monitoring the circuit II and the circuit III are arranged. The disturbances are evaluated in the same way as in FIG. 1. If only two light signal circuits are available, the winding 23 of the Tr2 can be split up for detecting the faults and arranged in the two lines 1 and 2 in such a way that the same display reliability is achieved in the event of faults. In order to detect the incident of contact and the incursions of external voltage in the lines 3 to 5 , z. B. corresponding windings 13 and 14 of the transformer Tr 1 in lines 3 and 5.

F i g. 3 shows an embodiment with two light signal circuits, which are connected to a three-wire feed line in such a way that the one signal aspect appears with the lamp L 1 via the transformer Tl and the lines 1 and 2 and after switching on the control relay S (represented by its windings SI and SII) switched off with the flip of the contact S2 and the other signal aspect with the lamp L2 via the transformer T 2 and the lines 2 and 3 is switched on.

In this case, for example, with the same power consumption of lamps L1 and L2, the two light signal circuits can be monitored for normal operating current by relay A with a transformer Trl, which in this case only has two windings 11 and 12. If the power consumption of the lamps L1 and L2 is different, the winding 11 of the transformer is divided into two windings in a manner known per se and designed so that it, arranged in the corresponding lines 1 and 3 , monitor the two normal operating states.

Another relay B is shown in FIG. 3 represented by its windings BI and BII. The one winding B 1 is dimensioned so that interference, z. B. by touching the feed lines with each other as well as by external voltage incidence, which cause a current greater than the maximum operating current, are displayed in the interlocking system. To check the functionality of this relay B, a winding B 1I is arranged in the dependency circuits of the signal control relay S.

If the signal aspect is to be switched on with the lamp L2, its contact ET is switched over by pressing the setting button and the relay B is excited via the winding B II. The relay B switches its contacts B 1 to B 3 . The connection circuit of the control relay S with the winding SI is closed via the contact B 3. The control relay picks up and changes its contacts S 1 and S 2. The signal lamp L2 is now switched on by the relocated contact S2, whereby the monitoring relay A remains energized with normal operating current. Relay B is still energized via contact ET. After releasing the set button, the contact ET is returned to the position shown in FIG. 3 position shown turned over. The circuit of relay B is interrupted. With the release of the relay B, the signal control relay S now holds itself in a self-closing circuit which leads via the contacts ET, A 1, S 1, B 1 and the winding SII of the relay S.

The signaling relay M is influenced via contacts A 2 and B 2 and, depending on its state, reports faults in the signal circuits via dependency circuits (not shown) in the interlocking system.

Claims (1)

Claims: 1. Circuit arrangement for monitoring light signals, in particular light signals fed by alternating current, in railway safety systems with several separately connectable light signal circuits, in which monitoring switching means are assigned to each light signal circuit which, depending on the magnitudes of the currents flowing in the switched on light signal circuits, or the normal operating states of the light signals in question See. disturbances in the circuits -zeichnet d a d u rch g e k hen that parts (windings 11 and 13 or 21 and 23, Fig. 1) of the monitoring switching means for at least two are not simultaneously turned on light signals (signal lamps Ll and L2) are arranged in a combined manner in the relevant light signal circuits (1 and II) that, due to the dimensioning of the switching means parts (windings 11 and 13 or 21 and 23), one monitoring switching means (A or B) over a specific light signal circuit (1 or II) at normal operating current (windings 11 or 21) and via the other light signal circuit (II or 1) only responds (windings 13 or 23) if the maximum operating current in this circuit (11 or 1) due to disturbances around a certain Amount is exceeded. 2. Circuit arrangement according to claim 1, characterized in that parts (windings 13 and 14, F i g. 2) of the monitoring switching means of a light signal circuit (I) are arranged in several light signal circuits (II and III) to display faults. 3. Circuit arrangement according to claim 1, characterized in that to display faults each part (windings 23 or 33, F i g. 2) of already existing monitoring switching means of further light signal circuits (II and III) in each of the two feed lines (1 and 2) a light signal circuit (I) is arranged. 4. Circuit arrangement according to claim 1, characterized in that in the presence of only two light signal circuits, the two light signals (signal lamps L 1 and L 2, F i g. 3) are connected via a three-wire feed line (1, 2 and 3) , a Part (winding B II) of the monitoring switching means (relay B) provided for displaying the faults in the light signal circuits is arranged in the dependency circuits of the signal setting relay (S).