DE4110990A1 - DEVICE FOR TESTING SIGNAL LAMPS IN RAILWAY SYSTEMS - Google Patents

Abstract

A device for cold filament testing signal lamps (L) which are located in the exterior system of a signal box and are fed via lamp transformers (LT). For the purpose of testing, the inductive resistor of the primary winding of the lamp transformer is evaluated. The primary winding is connected for this purpose in a measuring circuit which extends from a measurement voltage source (QM) via the cable conductors used for feeding lamps, and contains an inductive measuring resistor (W). The current flowing in the measuring resistor or the voltage dropping across the measuring resistor is evaluated by comparison with the corresponding measurement variable occurring when the measuring resistor is fed directly with the measurement voltage. <IMAGE>

Description

The invention relates to a device according to the preamble of Claim 1. Such a device is such. B. from "Eisenbahntechnische Praxis" 1959, volume 3, pages 25 to 26 known. With the help of a monitoring relay, the Flowing feed current monitored. Sinks Feed current below a predetermined, from the relapse of the Supervisor relay dependent threshold, so it falls Monitoring relay and reports the failure of the signal lamp.

There are a number of other circuits known to do this known device, especially with regard to its usability together with long cable leads, improve.

All of these known devices monitor the feed current and therefore require the operation of the signal lamp. Is the lamp switched dark, so it can with the above Facilities don't be monitored. A person entering during a break Failure is only noticed when the lamp is put into operation should be and then their service fails.  

Should the functionality of a signal lamp outside the Operating phases are checked, this requires one Cold thread monitoring, as z. B. from DE 34 19 121 C2, Claim 3 and column 4, lines 5 to 9 is known. Such Cold thread monitoring is carried out by means of special, on the Secondary side of the lamp transformer leading Monitoring circuits and requires a high additional Circuitry.

The invention has for its object a device specify a cold thread test of signal lamps from the signal box off, without monitoring switching means arranged in the external system allowed.

This object is achieved by the specified in claim 1 Features solved.

The device according to the invention takes advantage of the fact that the inductive resistance of the primary winding of the lamp transformer in Dependence of the ohmic effective at its secondary winding Signal lamp resistance changes.

To assess the resistance of the primary winding, this is described in certain time intervals, in series with a measuring resistor, in switched a measuring circuit. The one falling at the measuring resistor Voltage or the current flowing through the measuring resistor evaluated by a simple circuit. Besides the measuring resistor, the evaluation circuit and a measuring voltage source, all of which in the signal box, there are no additional circuit parts, especially no additional cable cores for cold thread testing needed. The measuring current is so small that the Signal lamp due to the measuring current can be safely excluded can.  

Embodiments of the device according to the invention describe the Subclaims 2 to 6.

So is the use of a voltage converter as a measuring resistor and simultaneous potential separator between signal current circuit and Evaluation circuit Subject of claim 2.

A capacitive coupling of the evaluation circuit to the Measuring resistor and the electrically isolated coupling via one Optocouplers provide claims 3 and 4.

The subject of claim 5, finally, enables little additional effort, simultaneous function monitoring of the circuit parts used for cold thread testing, while in Claim 6 the evaluation of the state of the signal lamp Measured variable that may already provide information existing and used for other purposes computer is described.

Using two figures, exemplary embodiments of the Device according to the invention described in detail and its Function explained.

Fig. 1 shows a block diagram of a simple apparatus according to the invention,

Fig. 2 shows a block diagram of a device according to the invention with function monitoring.

In Fig. 1, a signal lamp L is operated in a known manner via a lamp transformer LT. The lamp and lamp transformer are located in the outer area A of a signal box ST. The primary winding of the lamp transformer is connected to the interlocking device via a cable feed line up to 6.5 km long, which contains cable cores K 1 and K 2 . The alternating operating current, which the signal lamp draws from a supply device SP, flows via the primary winding of a monitor transformer UT, with the secondary winding of which a monitoring circuit US, not shown here, e.g. B. a monitoring relay is connected.

For the cold thread test are a measuring voltage source QM, here a easier, e.g. B. mains-fed isolating transformer, a schematic represented by a changeover contact of a relay Connection device AN, a voltage converter W and a Evaluation circuit AS provided.

In principle, the signal lamp can also be used as the measuring voltage source AC network used during the operating phases will. This makes a special measuring voltage transformer saved.

The connecting device alternately connects a first terminal of the measuring voltage source to one of the two cable wires K 1 or K 2 . The second terminal of the measuring voltage source is permanently connected to the cable core K 2 via the primary winding of the voltage converter.

A measuring current therefore constantly flows through the primary winding of the voltage converter, which, however, assumes different values, depending on which cable wire the first terminal of the measuring voltage source is connected to. If the measuring voltage is connected to the K 1 cable, the measuring current flows (with the signal lamp switched off, i.e. the signal lamp supply is disconnected) via the K 1 cable, the primary winding of the lamp transformer LT and the K 2 cable into the primary winding of the voltage converter W. If the measuring voltage is included the cable wire K 2 connected, it lies directly on the primary winding of the voltage converter and a measuring current dependent on the inductive resistance of the voltage converter is established.

The one flowing over the primary winding of the lamp transformer Measuring current must not be able to rise so high that the signal lamp is lit up. This is in trouble-free operation due to the high input impedance of the primary winding of the Voltage converter or a comparable inductive Measuring resistance guaranteed. To also in case of short circuit of the Measuring resistor or the evaluation device to ensure that If the measuring current does not reach too high values, it can additionally e.g. B. by appropriate design of the measuring voltage source forming transformer can be limited.

Is that induced in the secondary winding of the voltage converter Voltage is measured, so only one signal lamp is intact slight change depending on the clock of the switching device detected. The resistance of the cable cores and the resistance of the lamp transformers loaded by the signal lamp are small compared to the inductive resistance of the voltage converter. Kick however, if the lamp thread is interrupted, the secondary load of the lamp transformer and its Primary winding takes on a high inductive resistance. The Primary windings of the lamp transformer and the voltage converter then form an inductive voltage divider and those at the The primary winding of the voltage transformer drops the voltage about half of the directly measured measurement voltage.

The evaluation circuit is on the secondary side of the Voltage converter now determines an alternating voltage whose amplitude doubles or halves in time with the switching device. This change in amplitude can now be done with a predetermined value compared, which it surely exceeds in the event of filament breakage. It the submission of a fault report can be made dependent on this.

The device according to FIG. 2 differs from that according to FIG. 1 in that the two cable cores K 1 and K 2 are connected to measuring voltages of different phase positions.

To generate these different measuring voltages is the Transformer supplying measuring voltages (measuring voltage source QM) provided on the secondary side with a center tap that opens Reference potential (here earth potential) is set. Additionally contains the measuring voltage transformer has a second secondary winding Obtaining a comparison AC voltage.

The evaluation circuit is capacitive here via a capacitor C. to an inductive one used instead of the voltage converter Measuring resistor RM coupled. The latter behaves like that Primary winding of that used in the above embodiment Voltage converter and could also be replaced by one here will.

The evaluation circuit AS here contains a rectifier GL, one downstream low-pass filter TP and a threshold switch SW. In addition, a phase comparison circuit PH and a output-side AND gate UG available.

The AC voltage tapped off at the measuring resistor RM passes through the capacitor C to the input of the rectifier that it rectified and the low pass.

The low pass is dimensioned so that it the AC voltage frequency blocks, with the slower frequency of the switching device passing voltage changes on the other hand. These will, e.g. B. after another rectification, in the downstream Threshold switch with a predetermined threshold voltage UR compared. The output signal is not directly Fault message used, but previously in the output side And gate UG with the output signal of the phase comparison circuit PH conjunctively linked.  

This phase comparison circuit, which on the measuring resistor tapped voltage is also supplied, compares the Phase position of this voltage with the phase position of the am Measuring voltage transformer obtained comparison AC voltage. By phase sensitive rectification z. B. a AC signal with the frequency of the switching device be obtained, which, as above in connection with the test described the amplitude of the measured voltage, rectified and with the predetermined one supplied to the phase comparison circuit Reference voltage UR can be compared.

The output of the AND gate only then provides the intactness of the Signal lamp thread signal indicating an output line AL, if both those characteristic of the failure of the lamp thread Voltage changes at the measuring resistor fail as well Phase comparison circuit provides an output signal that the regular change of the phase position of the measuring resistor falling voltage.

A failure of the switching device, e.g. B. who otherwise does not notice would be recognized if there is no phase change.

Claims (6)

1. Device for cold thread testing of signal lamps located in the outdoor area of a signal box, which are fed via a cable feed and a lamp transformer located in the vicinity of the respective signal lamp from the signal box and are monitored during operation by evaluating the feed current, characterized in that a switching device in the signal box (AN) is provided which, when the signal lamp (L) is dark, connects the cable wires (K 1 , K 2 ) leading to the primary winding of the lamp transformer (LT) alternately with a terminal of a measuring AC voltage source (QM), the other terminal of which is connected via an inductive measuring resistor ( W) is connected to one of the cable wires and that an evaluation circuit (AS) is provided which measures the voltage drop occurring at the measuring resistor or the current flowing through the measuring resistor and then checks whether a change in the voltage drop occurring in the alternating cycle of the connecting device (AN) it or the current flowing through the measuring resistor exceeds a predetermined threshold value and triggers a fault message if this is the case. 2. Device according to claim 1, characterized in that the inductive measuring resistor through the primary winding of a Voltage transformer is formed and that the Evaluation circuit with the secondary winding this Voltage transformer is connected. 3. Device according to claim 1, characterized in that the Evaluation circuit is capacitively coupled to the measuring resistor. 4. Device according to claim 1, characterized in that the Evaluation circuit with the switching path of an optocoupler is connected, the light-emitting diode section of the measuring resistor is connected in parallel. 5. Device according to one of claims 1 to 3, characterized characterized in that the measuring voltage source (QM) two measuring voltages delivers opposite phase and the switching device each cable wire with a different terminal of the measuring voltage source connects and that the evaluation circuit a Phase comparison circuit (PH) contains the phase position of the am Measuring resistance falling voltage or that by the Measuring resistance flowing current with the phase position of one of the Compares measuring voltages and issues a fault message if none The phase position changes in time with the switching device. 6. Device according to claim 1 to 5, characterized in that the evaluation circuit is a computer with an upstream Analog / digital converter is.