DE1179984B - Circuit arrangement for monitoring operations, in particular track occupation and signal settings on railway lines - Google Patents

Description

Circuit arrangement for monitoring operating processes, in particular of track occupation and signal positions on railway lines The invention relates to a circuit arrangement for monitoring operations with display on a Illuminated image and / or for registering, in particular, equal occupations and signal positions on railway lines, in the central office a step switch and in the by means of direct current or frequency pulses with the control center via a two-wire Remote line interacting zones connected in a chain, one call receiver each, a relay chain and frequency generator are provided.

Basically, in such circuit arrangements, the one to be monitored Object equipped with a test contact and its closed or open Transfer position to a relay located in the central office, which then with his contacts actuated a display or registration device. The different known arrangements differ essentially in the type of cooperation between the central office and the object to be monitored.

A circuit arrangement is known in which both the central office as well as stepping mechanisms are provided in each test group, which are provided by the central office controlled synchronously by means of inductive pulses and fine relays. The disadvantage Such arrangements are based on a relatively high cost of relays with a high switching frequency and the resulting wear; also are used. Fine relay quite prone to failure, and if they fail, the synchronous running of the stepping mechanisms becomes disturbed, so that false reports occur.

Circuit arrangements are also known in which a stepping mechanism A relay chain can be used in the central office and in each reporting group. In such arrangements, it is common to use the control and signaling pulses as direct current or to transmit inductive pulses over the long-distance line. When using direct current pulses however, only insufficient distances can be bridged. Because of the engagement The transmission distances can be made a bit cheaper with fine relays, but because of the higher susceptibility of the precision relay to failure, a lower one must be used Security of the transfer must be accepted. But also the use of Inductive pulses have significant disadvantages. Due to the extremely short duration of action These inductive pulses tend to be such arrangements in spite of the use of fine relays easy to transmission interference. In addition, there are disturbances caused by external influences develop. Monitoring devices are known in these circuit arrangements which the correspondence of the number of received pulses with the number of determine required pulses at the end of the scanning cycle and in the case of 'a Switch off the entire system if there is any difference. This arrangement has the disadvantage that at Incorrect impulses the synchronism is disturbed and numerous false reports follow, before a correction can be made. The location of the fault cannot be used either to be determined.

In another known circuit arrangement, each is to be monitored Object is assigned a specific frequency that is sent to the control center when the status changes is transmitted. Although this facility changes state with very little Indicates time delay, the technical effort is very considerable, since for each frequency a corresponding filter and a receiver are required. As is well known, can but on a normal telephone line because of the required frequency spacing only twenty-four different frequencies are used simultaneously; that means, that when monitoring more than twenty-four objects with carrier frequency devices would have to be worked, whereby the technical effort increases considerably.

Finally, circuit arrangements are known in which a Clock is arranged so that all reporting points as well as the control center at the same time can be set to a specific reporting step and thus synchronous forwarding of all counters present in the named places. About this synchronism between reporting offices and to reach headquarters, it is imperative It is necessary that the clock is arranged as close as possible to the most distant station otherwise the runtimes of the impulses from the clock generator or from the reporting points to the head office are different. The switched on cyclically by means of the clock Query frequency is used for pulse-wise forwarding of the in the individual reporting groups and the meter located in the control center. The susceptibility of such systems to failure is also significant.

The invention is based on the object with the least possible technical The greatest possible transmission security with a relatively large range to achieve.

According to the invention, this object can be achieved in such a way that a Call generator located in the central station with one assigned to each reporting group known call receiver is connected, which after incentives by a certain, The relay chain runs automatically for the call frequency applied for the query period lets that each relay chain with any number of test contacts a control relay and two signal relays are assigned whose contacts are in the same signal group associated, multiple frequencies generating frequency generator are located, which in turn in a known manner with receivers tuned to the various frequencies generated is connected in the central office, and that in the central office independently of the control and signaling impulse evaluation an immediately switches off the arrangement in the event of missing impulses Pulse monitoring with simultaneous fault location display is provided.

The main advantage of the invention is that they are in contrast to the known arrangements z. B. also for routes with electric train conveyance can be used without special precautions being necessary. Another The advantage is that the frequency pulses can be chosen so long that they a Make up a multiple of the response time of the corresponding relay and thus this Make sure to let the relay pick up. Due to the type of pulse monitoring according to the Invention can not only dispense with an acknowledgment, but by switching off The arrangement in the case of missing pulses also makes it much easier to determine the location of the fault will. Of particular importance, however, is that the circuit arrangement according to the invention allows the number of frequencies required while maintaining a limit the large number of objects to be monitored to a total of only four.

In a further embodiment of the invention it is provided that a cut-off relay and a through relay in the circuit of the last chain relay of the relay chain are provided, and NC contacts of the cut-off relay in connection with a the transmission transformer forming the line termination as well as the closing contacts of the through switch relay are arranged in series with the pipeline.

This measure prevents reflections on the long-distance line, since this is completed at every point in time during operation.

To return to the "arrangement" after querying the last zone to be able to switch off is provided according to a further feature of the invention that according to the relay that corresponds to the last object to be monitored in the last reporting group is assigned, a relay of the same type is provided, the test contact of which is always closed is.

On the basis of an embodiment shown in the drawing the subject of the invention is intended to be used in the example shown is formed on railway lines, are explained in more detail.

In the drawing, the central point ZS is shown with only one reporting group MG . Of course, a different number of reporting groups, all of which are designed in the same way, can be connected in a chain-like manner to the central point ZS via the long-distance line FL.

The central station essentially consists of a call generator RG, which sends out the call frequency f 1 , the transmitters U1 and U2, the receivers E1, E2 and E3, a step switch, a pulse monitor JU and the lamps L 1 to L n provided for display with the associated display relays P 1 to P n.

The alarm groups MG are preferably arranged in interlockings along the route and each consist of a galvanically separated trunk line connection box FIK, in which the transmitter U3 and U4 as well as a switching relay U and a switching relay B with their contacts u 1, u 2 and u 3 or .b 1 and b 2 are arranged, as well as a call receiver RE, a relay chain RK and a frequency generator FG with the associated relays ST, MI and M II for generating the control frequency f 2 and the two reporting frequencies 13 and f 4.

The call generator RG sends the call frequency f 1 from the central station ZS via the transmitter U 1 to the long-distance line FL. This calling frequency f 1 is received in the first reporting group MG via the high-resistance coupled transmitter U3 by the calling receiver RE, whose relay A picks up and, with its contact a, starts the relay chain RK. During the course of the first step, this actuates the control relay ST, which sets the frequency generator FG to the control frequency f 2 with its contact st , and then in each subsequent step, depending on the position of the test contacts k1 to kn, one of the signaling relays MI or M II. The signal relay MI picks up, for example, when the test contact that has just been switched on is closed; the contact m 1 is thereby closed, and the frequency generator FG then sends the message "test contact closed" to the central station ZS with its reporting frequency f 3. If the test contact just switched on is open, however, the signal relay MII picks up, and the contact mII is closed, so that the frequency generator FG with the reporting frequency f 4 gives the opposite message to the central station ZS.

The control and signaling pulses transmitted by the frequency generator FG at frequencies f 2 to f 4 reach the central point ZS via the transformer U4, the long-distance line FL and the transformer U 2. With the filters located in the receivers E1, E2 and E3 and tuned to the respective frequencies, it is ensured that the actuating pulse f 2 is picked up by the receiver E 1 in any case. Depending on this, the control receiving device STE attracts and closes the circuit of the step switch S with its contact ste 1. This switches one step further and prepares the circuit for the indicator relay P 1 by switching it on to the receivers E2 and E3. If the message pulse following the control pulse has the frequency f 3, it reaches the receiver E2 and there actuates the message receiving relay MEI. Its contact me 1 1 applies negative potential to the relay P 1 and lets it attract; it then holds itself via its own contact p 11. Another contact p 12 of the relay P 1 switches on a lamp L 1 with which the arrival of the said message is indicated (for example in a corresponding symbol in a monitoring object). If, however, the actuating pulse is followed by frequency f 4 and thus the opposite message instead of frequency f 3, the message receiving relay MEII attracts in receiver E3, which closes its contact me Il 1 and thus applies positive potential to indicator relay P 1, so that this either cannot pick up (because both winding ends are at positive potential), or its winding is short-circuited via the still closed contact p 11 if the relay was still picked up from the previous test cycle. This means that the lamp L 1 cannot be switched on either; the corresponding symbol remains unlit.

Such a message is followed by an actuating pulse with the frequency f 2, which initiates the message about the position of contact k2 in alarm group MG. When the standing impulse arrives in the receiver E 1, the step switch S is turned over advanced one step; when the new message pulse arrives with the Frequency f 3 the relay P 2 is switched on (or it remains de-energized when the Signal pulse has the frequency f 4), so that the lamp L 2 is switched on via the contact p 22 is turned off or remains off.

If the relay chain RK has now expired in the message group MG, the switching relay U in the trunk line connection box FLK responds and with its contacts u 1 and u 2 switches the trunk line FL and thus the uninterrupted ringing frequency f 1 to the next message group, which is then also in works the way already described. Another contact u 3 of the switching relay U switches on a delayed switch-off relay B , which with its contacts b 1 and b 2 switches off the transformer U4 of the first reporting group previously queried from the trunk line. This forwarding is repeated in each alarm group (with the exception of the last one) after the relay chain belonging to each alarm group has expired.

After the relay chain has expired in the last reporting group, the entire arrangement is switched to its starting position in such a way that the relay that is assigned to the last object to be monitored is followed by a relay of the same type whose test contact kn is always closed. As a result, when switched on by the relay chain RK, this relay causes a signaling pulse after the actuating pulse, in the manner already described, which always has the frequency f 3. This then switches on the switch-back relay P n in the central point ZS in the same way as was described for the display relay P 1. A contact pn of the switch-back relay P n switches off the call generator RG, so that all relays A in the call receivers RE of the individual reporting groups MG also drop out and so that the relay chains RK are also shut down. The arrangement is ready for operation again as soon as the switch-back relay P h drops out.

The JÜ pulse monitoring is intended to ensure that an actuating pulse and a signaling pulse always follow one another in the correct order. For this purpose, working contacts ste 2, me I 2 and me I 12 of the control receiving relay STE and the message receiving relays ME I and ME II are arranged in parallel at the two inputs of the pulse monitoring JU so that the contact ste 2 is in front of one input and the two contacts me I and rne II are parallel to each other in front of the second entrance. If the actuating reception relay STE now picks up when an actuating pulse arrives, then der.Kontakt ste2 is closed and the pulse monitoring JU (which can, for example, be a bistable multivibrator known per se) receives a pulse; the connected closed-circuit relay Y, which is normally picked up, remains picked up. The next impulse that follows must be given to the relay Y with the contacts me 1 2 and me 1 12 when one of the two message receiving relays MEI and Me II is picked up. However, if it does not occur and instead another pulse follows via the ste 2 contact, the bistable multivibrator in the pulse monitoring JÜ is already in the position now required from the previous control pulse. Since the relay Y only remains attracted after the multivibrator has been tilted, it now drops out because the tilting process does not take place and opens its contact y in the line of the call generator RG. However, this means that no more calling frequency f 1 can go out to the reporting groups MG, and the query process is interrupted. From the then existing position of the step switch S, it is easy to determine the location of the fault.

This circuit arrangement can be tailored to the respective requirements can also be used advantageously for monitoring industrial plants.

Claims (3)

Claims: 1. Circuit arrangement for monitoring operating processes with display on a light image and / or for registering, in particular, track occupation and signal positions on railway lines, in which a step switch in the central station and in which cooperate with the central station via a two-wire long-distance line by means of direct current or frequency pulses , in chain-connected reporting groups a call receiver, a relay chain and frequency generator are provided, characterized by the fact that a call generator (RG) located in the central station (ZS) is connected to a paging receiver (RE) that is known per se and assigned to each reporting group (MG) , which, after stimulation by a certain call frequency (f 1) applied for the query duration, allows the relay chain (RK) to run automatically so that each relay chain with any number of test contacts (k 1 to kn) has an actuating relay (ST) and two signal relays (MI and MII) are assigned whose contacts (st and mI or m11) sic h located in the frequency generator (FG) which is assigned to the same reporting group and generates several frequencies (f 2, f 3 and f 4), which in turn is located in the central office in a known manner with receivers (EI, E 2 and E3) matched to the different frequencies generated is connected, and that a pulse monitoring system (JU) with simultaneous fault location display is provided in the central station independently of the control and signaling pulse evaluation. 2. Circuit arrangement according to claim 1, characterized in that a switch-off relay (B) and a switch-through relay (U) are provided in the circuit of the last chain relay of the relay chain (RK) and normally closed contacts (b 1 and b 2) of the cut-off relay in connection with one of the Transmitter transformer (fI4) forming the line termination as well as normally open contacts (u1 and u2) of the switching relay are arranged in series with the long-distance line (FL). 3. Circuit arrangement according to claim 1 and 2 for switching off after querying the last reporting group, characterized in that a relay of the same type is provided after that relay which is assigned to the last object to be monitored of the last reporting group, the test contact (kn) of which is always closed is. Documents considered: German Patent No. 1047 830; Patent documents No. 14 227, 18 968, 15 531 of the Office for Inventions and Patents in the Soviet zone of occupation of Germany; Austrian Patent No. 203 057; Book "Basis der Fernsprechtechnik" by Fuehrer, 1941, fig. 51, p. 99; Magazine "Signal und Draht", issue 2, 1960, p. 37; Journal "Deutsche Eisenbahntechnik", Issue 4, 1957, pp. 177 to 181.