RU2185633C2 - Circuit to detect and test light signals - Google Patents

Abstract

FIELD: control over light signals on railroads. SUBSTANCE: control relays without forced make or break of switching contacts are used to switch on lamps of reliable light signal instead of signal relays. Control relays are so structurally designed that individual switching contacts while frozen together in one position will not be any more thrown over when reversed. Contacts are so placed in feeding lines of signal lamps that mechanical fixation of one contact is displayed at the latest under load following onset of this defect thanks to subsequent process of setting. It takes place due to fact that corresponding signal lamp can not be cut in any more and that certain test messages are missed. EFFECT: enhanced functional reliability of circuit. 9 cl, 6 dwg

Description

 The invention relates to a circuit according to the preamble of claim 1. A similar circuit is known from DE-PS 2255200. There, a circuit for relay-controlled electrical circuits for determining the contact of conductors is disclosed, which is bypassed by a single monitoring relay for monitoring the enable and stop lamps of the light signal. To connect the enable signal lamp, two executive bodies are connected one after another, of which the actuator, which is initially triggered when it is activated, disconnects the control relay included in the stop signal circuit and applies a single-pole voltage to the connected enable signal lamp through the winding of the still disabled control relay. Due to the deliberate shutdown of the monitoring relay when changing the Stop position to Enabled, this monitoring relay is subjected to a drop check. Immediately after switching on the first executive body, the second executive body is also included. He interrupts with one contact the circuit still closed so far for the lamp of the stop signal and sequentially closes the second core to the lamp of the enable signal. With the correct working state of the light signal, the control relay is again activated, and the direction of the current in the control relay has changed in comparison with the direction when the stop lamp is connected.

 Thus, when checking the release of the contacts at the beginning of the actuating body, the current direction for the control device is reversed for connecting the enable signal lamp. If the enable signal circuit when the enable signal lamp is connected at any time has contact with the stop lamp residential lamp, then the monitoring relay is released due to a short circuit.

 This known scheme for the implementation of the above switching cycle depends on the fact that the contacts of the corresponding executive bodies are switched at the same time. This means that the actuators must be designed as signal relays with force-closing or opening contacts.

 The present invention is such a further development of the known circuit according to the restrictive part of claim 1 of the claims so that instead of signal relays it is possible to use conventional control relays, which should be selected solely according to the electrical operating conditions, the required reliability and costs.

 The invention solves this problem by applying the distinctive features of paragraph 1 of the claims. Preferred forms of implementation and development of the inventive scheme are indicated in the dependent claims.

The invention is explained below in more detail using the drawings, where
in FIG. 1 shows the inclusion of a circuit according to the invention in a control and monitoring circuit of a light signal with a stop lamp and an enable signal lamp,
in FIG. 2 to 5 are diagrams with respectively one welded changeover contact,
in FIG. 6 is a diagram with several stop and enable lamps that are controlled and monitored through standard signal modules.

 Schematically shown in figure 1, the light signal LS is equipped with an enable signal lamp LG and a stop lamp LR, which are alternately connected centralization post. For this, both signal lamps are also connected through the longer supply lines L1, L2 to the internal installation of the centralization station through the schematically shown also. To switch the signal lamps, actuators S0 and S1, connected in a known manner, one after the other from the centralization station, are used. The centralization post is represented by a reliable computing system, one channel of which serves one executive body, and the other channel - another executive body. Channel separation is shown in FIG. 1 dashed lines. Dashed lines indicate a permanent loss of potential separation between the individual components of the circuit.

 Both actuators S0 and S1, in contrast to the prior art, are not designed as signal relays with forced closing or opening of the closing and opening contacts, but as control relays without forced closing or opening of the switching contacts S0 / 1 and S0 / 2 or S1 / 1. They are calculated mechanically so that individual switching contacts, if they are welded in one position, can no longer switch when reversing the corresponding relay; the NC contact remains closed and the NC contact remains open; this means that in the event of a malfunction, one of the considered switching contacts is mechanically fixed, while the other switching contact of the relay continues to work correctly.

 In FIG. 1 shows the connection of the LR brake light lamp LS. The power of the signal lamp comes from an ac voltage source operating without grounding. The supply current passes through the contact S1 / 1 of the executive body S1 closed in the initial position of the actuator S1, the line L2 to the stop lamp LR, the brake lamp LR, the control device U included in the power circuit and the contacts closed in the initial position of the actuator S1 S0 / 2 and S0 / 1 of the executive body S0. At the same time, in the control device U on the resistor Rx, a signaling voltage corresponding to the supply current is obtained, which, through the optic-electronic communication element OK3, is supplied to separate the potential to the two-threshold discriminator FD for evaluation. We will dwell on this two-threshold discriminator later in more detail.

 In the following, it is assumed that the light signal LS should show a resolution indication of the signal. To this end, the control computing system through one channel first includes an actuator S0 and then through another channel, an actuator S1. When the actuator S0 is connected, its switching contacts S0 / 1 and S0 / 2 are switched to another switching position, respectively. In this case, both switching contacts interrupt the power supply going through the control device U for the still-connected stop lamp LR, which, however, does not go out, since the power remains, and then through the bypass switching contact S0 / 2, the control device U, switching contact S0 /1. The signaling voltage on the short-circuited resistor Rx now immediately drops, so that the control device U switches to a no-current state (release check). Through the contact S0 / 1, the resistor Rx and the contact S0 / 2, the LG signal lamp is now turned on unipolar. If at one time leading on one of the resolving signal leads to the lamp due to contact between the wires, for example, to the cable leading to the stop lamp, or due to the input voltage of an external source, the opposite potential lies, then the signaling voltage appears on the resistor Rx, which detect with a two-threshold discriminator. The two-threshold discriminator then issues an appropriate control message to the evaluating computer system, which, from an untimely control message, draws a conclusion about the malfunction and causes a certain reaction to this, which under certain circumstances may consist in shutting down the executive body S0. In this case, the unipolar closed power circuit to the lamp of the enable signal LG is interrupted, and the stop lamp LG is reconnected.

 If the above-mentioned malfunction does not occur, that is, the control device U, after connecting the actuator S0, was subjected to a drop test, then the computer system also connects the actuator S1 with a delay, and its switching contact S1 / 1 switches. In this case, the existing stop signal current circuit is interrupted and the second core is connected in series to the LG enable signal lamp. The power supply and control circuit for this signal lamp passes through the contact S1 / 1 of the executive body S1 closed in the working position of the second actuator, the L1 lines and the signal lamp LG, the contact S0 / 2 of the actuator S0 closed in the working position of the first actuator, the resistor Rx and contact S0 / 1 of the first executive body.

 Due to the use of the control relay without forced closing or opening of the switching contacts, a case may arise that the contacts controlled by the relay S0 do not work synchronously further. This takes place when one of the contacts S0 / 1, S0 / 2 is welded. This contact is then mechanically fixed, while the other relay contact continues to work correctly. Using FIG. 2-5 below, what happens when one of the contacts is fixed in one or the other position; the corresponding contact and its positions are especially highlighted in the drawings by thicker lines. The monitoring device U is symbolically represented by a relay coil.

 In the embodiment of FIG. 2, the signal module SM shows that the contact S0 / 1 of the actuator S0 is welded in the position in which it fell when the LR brake light was connected. If the executive body S0 is now connected to connect the resolving indication of the signal, then only contact S0 / 2 is switched over. In this case, the power circuit for the still connected brake light lamp LR is interrupted and the control device U (as expected) is released. By connecting the actuator S1, its switching contact S1 / 1 is switched. In this case, the second core to the stop lamp is disconnected and the corresponding core to the LG enable signal lamp is simultaneously connected in series. The enable lamp, however, cannot be ignited because the power circuit is interrupted through the mechanically fixed contact S0 / 1 of the first actuator. The control device U signals the detected operational state to a centralizing station, which is thereby informed of a signal malfunction.

 In FIG. 3 shows that the same switching contact is fixed in a different position. In this position, the control message of the control device U is absent, so that the centralizing station can make a conclusion about the malfunction that has occurred and does not give a command to enable this signal.

 In Fig. 4, the switching contact S0 / 2 of the first actuator is fixed in the mechanical position to which it falls when the lamp of the enable signal LG is connected unipolarly. As a consequence of this, with a later turn-off of the enable lamp LG and connection of the stop lamp LG, the corresponding control message of the control device U is absent; the centralizing post is informed of the occurrence of a malfunction by the absence of a control message.

 In FIG. 5 shows that the same switching contact is in a different position for a long time. It falls into this position when the LG enable signal lamp is turned off.

 As a result of mechanical locking of the S0 / 2 contact, the enable lamp is not connected. There is no corresponding control message; In this way, a malfunction can be recognized.

 If the contact S1 / 1 is welded in one or another position, it prevents the LR brake light lamp or LG enable signal lamp from connecting. The control message of the control device related to this informs the centralization station of the malfunction that has occurred.

 From the above it follows that the claimed control circuit with its switching contacts without forcing or opening is as reliable as the circuit already known from DE-PS 2255200, in which signal relays with forcibly closing or opening opening and closing contacts are used. A contact defect is manifested at the latest when the load of the signal lamp follows the occurrence of the defect, and when the defective is activated.

 As already explained, the current flowing through the correspondingly connected filament of the lamp of the lamp creates a signaling voltage in the resistor Rx, which is applied to the two-threshold discriminator FD through the optoelectronic coupling element OK3 for evaluation. The principle of operation of this two-threshold discriminator is explained in detail in the German utility model 9411807. The current supply of the two-threshold discriminator is from a constant voltage DC voltage source. A control message, that is, information on whether the detected lamp current is respectively within the specified tolerances or not, is given through the next optoelectronic communication element OK1 to the evaluating computer system and is processed independently in each channel of the computer there. To control different current windows for day and night operation, a two-threshold discriminator can be set at different switching thresholds. This happens through the optoelectronic communication element OK2, to which the corresponding control potentials can be supplied from the centralization station. The two-threshold discriminator can be subjected to a functional check in such a way that the switching thresholds it controls are temporarily changed, and it is checked whether the current lamp current lies in the current window for night operation or, accordingly, in the current window for daytime operation and does not go beyond certain limits of the switching thresholds. Optoelectronic communication elements for the lossless separation of the potential of the circuit from the channels of the computer are made in the form of a reliable design. Due to the not presented monitoring of the state of insulation relative to the ground, earth faults of light signal electric circuits operating isolated from the ground can be detected.

 Depending on the lamp power of the respective signal lamps, different lamp currents flow, and different signaling voltages also appear on the measuring resistance Rx. To equalize these alarm voltages to a certain value, the same for all lamp powers, the measuring resistor Rx is made with the possibility of adjustment; its value decreases with increasing lamp power.

 In a more detailed example of the embodiment of the circuit according to the invention, it was shown that the light signal to be controlled and controlled must have an alternately connected stop lamp and an enable signal lamp, and that a two-threshold discriminator is assigned to this light signal to control one or the other lamp current. In fact, however, light signals can have more than two alternately connected signal lamps, in particular if these light signals contain both a main and a warning signal. In order to keep control over current of lamp currents low, the form for the further development of the circuit according to the invention provides that signaling voltages from a plurality of signal lamps are cyclically connected to a common two-threshold discriminator and certain measurement values are stored in the evaluating computer system for as long as they are updated with new ones measurement results. Due to special circuit measures, it should be ensured that there really is a cyclic connection of the alarm voltages allocated from various lamp currents.

 According to a preferred embodiment of the invention, the discriminator is intended to cyclically monitor a total of four signal partial modules with respectively one or two alternately connected signal lamps. A circuit diagram of such signal partial modules is shown in FIG. 6. Each signal partial module SM1 to SM4 has already explained switching contacts S01 / 1, S01 / 2, S011 / 1; S02 / 2, S02 / 2, S012 / 1; S03 / 1, S03 / 2, S013 / 1; S04 / 1, S04 / 2, S014 / 1 from two control relays and the corresponding control device U1 to U4, which is represented by measuring resistors, on which signaling voltages removed from the lamp currents can be removed for a two-threshold discriminator. The contacts of the control relays are indicated in the same way as in figure 1, and are only supplemented by current numbers after designating the corresponding control relay to which they relate. As can be seen, the stop lamp LR1 and the enable signal lamp LG1 are connected to the partial actuator module SM1, as is also the case in FIG. By alternately connecting one or the other signal lamp, the signal voltage to be evaluated must be unambiguously associated with one or the other signal lamp. In the remaining partial executive modules, there is only one single signal lamp LG2, LR2 or LG3, respectively. Each time, depending on whether it is an enable signal lamp or a stop lamp, the supply lines to the signal lamps are connected to one or the other pair of output terminals corresponding partial signal module, namely in exactly the same way as the signal lamps according to figure 1. Thus, it is achieved that for the control and monitoring of light signals of any design it is always possible to resort to the same signal partial modules. Each signal partial module is able to control and control the corresponding signal lamp or corresponding signal lamps, moreover, conventional control relays with switching contacts are used as switching means. Possible welding of the contacts becomes noticeable at the latest when the installation process is started, in which the welding of the contacts occurred before that. The welding of the contacts with respect to the control messages has the same effect as the contacts of the wires between the wires of the brake light signal and the enable signal of the same light signal or different light signals located at the opposite potential.

 Instead of a control and monitoring centralization station, another control and monitoring device, for example, a computing system separate from the centralization station, may also be provided.

Claims (10)

 1. A circuit for monitoring light signals (LS) with one control device (U) for brake lights and / or enable signal (LR and / or LG), which is connected through the contacts of two actuators activated one after another in a delay power lines (L1, L2) of said signal lamps to the stop signal or enable signal circuit, and the control device (U) when the stop lamp (LR) is turned off or when the enable lamp (LG) is unipolarly connected through two contacts connected with delay one by one control system, undergoes a release test, in which the contacts of the initially switched on actuator, preparatively for connecting the lamp (LG) of the enable signal, reverse the current direction for the control device (U), characterized in that at least the switched on actuator is made in the form of a control relay (S0 ) with two switching contacts (S0 / 1, S0 / 2), of which the first switching contact (S0 / 1) serves to reverse the current direction for the control device (U), and the second switching contact contact (S0 / 2), connected between the first switching contact (S0 / 1) and the control device (U), when the stop lamp (LR) is turned off or, respectively, when the enable signal lamp (LG) is unipolar, in addition to the first switching contact ( S0 / 1) opens the corresponding current path through the stop lamp and, by connecting to a control device, unipolar closes the corresponding current path through the enable signal lamp.  2. The circuit according to claim 1, characterized in that the second actuator is made in the form of a control relay (S1) with a switching contact (S1 / 1).  3. The circuit according to claim 2, characterized in that each control relay (S0, S1) is mechanically designed so that the switching contact, if it is welded in one position, no longer switches over when the corresponding relay is reversed - the opening contact remains closed, and the closing contact open.  4. The circuit according to claim 2 or 3, characterized in that it additionally contains a corresponding number of similarly executed signal partial modules (SM), each of which is made on the switching contacts of the control relay and the corresponding control device and to each of which through the corresponding supply lines either at least one enable lamp and one stop lamp (LG1, LR1), or at least one stop lamp or enable (LG2, LR2, LR3) are connected.  5. The circuit according to claim 2 or 3, characterized in that the pairwise interacting control relays (S0, S1) are configured to control one reliable computer system.  6. The circuit according to claim 1, characterized in that the control device (U), if necessary, is set to different switching thresholds.  7. The circuit according to claim 6, characterized in that the control device (U) contains an adjustable resistor (Rx) included in the power circuit of the monitored signal lamp (LR, LG), the signaling voltage of which is supplied for evaluation to a two-threshold discriminator (FD).  8. The circuit according to claim 7, characterized in that the two-threshold discriminator (FD) is configured to control signal lamps (LR1, LG1, LG2, LR2, LR3) from a plurality of signal partial modules by cyclic connection of the detected in various signal partial modules (SM ) alarm voltage.  9. The circuit according to claim 7 or 8, characterized in that the output of the signaling voltages to the two-threshold discriminator (FD) and the transmission of the corresponding evaluation result from it to the evaluating computer system respectively occurs through an optoelectronic communication element (OK3, OK1).  10. Scheme according to any one of paragraphs. 1-9, characterized in that the signal lamps (LR, LS) operate isolated from the ground.

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