DE1152131B - Circuit arrangement for railway signal systems for the transmission of characters between two stations via a two-wire line - Google Patents

Description

Circuit arrangement for railway signal systems for the transmission of Character between two stations via a two-wire line The invention relates to a circuit arrangement for railway signal systems for the transmission of characters between two stations via a two-wire line, with both stations set up are that they can either serve as a sending station or a receiving station, and are each provided with one or more AC power sources that are used during a short periods of time generate alternating currents of certain frequencies and to the two-wire Line can deliver to a circuit in the receiving station accordingly to produce the character to be transmitted, this current circuit means in the Sending station generated direct current is maintained.

Known circuit arrangements of the above type, which are derived from the usual Telephony technology are taken, are in their application to railway signal systems not sufficiently reliable and stress the supply sources of the operating voltages undesirable in such a way that only a low efficiency of the converter units is obtained.

It has already become known for a decadal transmission multi-digit numbers in telecommunication systems power surges of different types of current or Transmit frequency at the same time. Such a circuit arrangement is in Systems where energy consumption is so low due to transmission difficulties must be kept as possible, not suitable; because the circuits that work for this known transmission used are intended to withstand power surges during prolonged periods To be able to submit periods of time, d. i.e., these arrangements are intended for systems which are so abundantly supplied with energy (alternating current or direct current) that Efficiency aspects are not important, and where personnel is always available for monitoring, changing batteries, etc.

It has also been suggested over a longer time interval for the simultaneous transmission of several different information in telephone systems to send alternating direct current and alternating current with selector operation, the The direct current is interrupted at the receiving location. Such a transfer, too is not for an arrangement that is in a distant, inaccessible place suitable.

After all, it is known to be used in telecommunications systems during chain calls to prevent a connection line as soon as the first connection is terminated is released. This is done in such a way that when the operator reports indirectly via a connection path to the next participant called in preparation Switching means become effective in the connection path and also when this is re-attached Participant remain effective, so that an identifier for the connection line this next participant is saved in the connection path. This circuit is using Direct current and alternating current operated not at the same time from the control center be sent, the direct current being sent from the receiving station.

In the case of railway signal systems, it can sometimes be for safety reasons It is important to have a station that gives a specific answer to a question from a remote station submitted, this answer can change quickly if necessary. In such Cases it is not appropriate that as in the last-mentioned known circuit the interruption of the direct current takes place at the receiving location; because then the In the event that the station at the receiving location has seized a common line, before the answer has been changed. The object of the invention is Creation of an improved circuit arrangement for railway signal systems of above type, which works extremely reliably, is insensitive to interference and at Use in locations where AC power is not available, the uses existing DC batteries as efficiently as possible.

This is achieved according to the invention in that the direct current power at the same time as the alternating current power is generated that by the alternating current in the receiving station a relay connected to the line via a contact is excited, which prevents direct current from the receiving station via its contact is supplied via the line to the transmitting station, and that by the direct current remains energized from the transmitting station, and that furthermore the DC circuit through Alternating current generated in the receiving station is interrupted in the sending station in the manner is that by the alternating current in the transmitting station one to the line via one other contact connected relay is energized, which prevents over its Contact direct current is supplied from the transmitting station to the line.

The invention is based on the embodiment shown in the drawing described, wherein Fig. 1 shows in detail how the transmission of a character takes place between two stations according to the invention, and FIG. 2 schematically shows an arrangement in which the transmission of several characters is possible.

In. Fig. 1, L is a two-core line between two stations A and B. A direct current line LsA connects a direct current battery to the line L via two inductors 1A. A signal switch CA is connected to the negative pole of a voltage source, and when this signal switch is in position 1A, an adjustable relay SA is energized. The relay SA has four normally open contacts SA 1, SA 2, SA 3 and SA 4. The normally open contact SA 1 is in the direct current line LsA, the contact SA 2 connects the normally open contact of the relay RA with terminal 1A, the normally open contact SA 3 closes a circuit for the relay RA via a capacitor AC, and the normally open contact SA 4 feeds a signal lamp AS. The relay RA has a normally open contact RA 1 and is kept attracted during the charging of the capacitor AC for a predetermined, relatively short period of time, for example 6 seconds. When relay RA is energized and contacts SA 2 and RA 1 are closed, the input terminals of an inverter GA 60 are connected to the positive and negative poles of a direct current source, and the inverter generates alternating current power at a frequency of 60 Hz. The output terminals of the inverter GA 60 are connected to an alternating current line vsA, which in turn is connected to line L. The input terminals of a frequency converter FA 38 are connected to the alternating current line vsA, this frequency converter generating alternating current power at a frequency of 38 Hz. On the output side of the frequency converter receiving a relay MA is present, which has a overall in the DC line LSA switched closed contact MA 1 and MA 2 a make contact, which connects a relay LBA to the line L. The relay LBA has a break contact LBA 1, which is in the direct current line LsA, a make contact LBA 2, which is parallel to the make contact MA 2 , and a make contact LBA 3, which is in series with a signaling device that consists of a lamp with a predetermined Light or a siren or possibly a combination of lamp and siren.

Station B is provided in the same way with a direct current line LSB which connects a battery to line L via two inductors 1B. A signal switch CB is connected to the negative pole of a voltage source, and when the signal switch is in position 2 B, an adjustable relay SB is energized. The relay SB has four working contacts SB 1, SB 2, SB 3 and SB 4. The contact SB 1 is in the direct current line LsB, the contact SB 2 connects the working contact RB 2 of a relay RB with the negative pole of a voltage source. A relay RB is excited via contact SB 3 via a capacitor BC and a circuit for a signal lamp BS is closed by contact SB 4. The relay RB has a normally closed contact RB 1 and a normally open contact RB 2 and is kept attracted during the charging of the capacitor BC for a certain short period of time, for example 6 seconds. When relay RB is energized, the input terminals of an inverter are connected to the positive and negative poles of a DC power source via contacts RB 2 and SB 2 , and the inverter generates AC power at a frequency of 38 Hz. The output terminals of inverter GB 38 are connected to a AC line vsB connected, which in turn is connected to line L. The input terminals of a frequency converter FB 60 are also connected to the alternating current line vsB, the frequency converter supplying alternating current at a frequency of 60 Hz. A receiving relay MB is connected to the output side of the frequency converter and has a normally closed contact MB 1 connected to the direct current line LsB and a normally open contact MB 2 which connects a relay LAB to the line L via contact RB 1 in the rest position. The relay LAB has a lying in the DC line LSB closed contact LAB 1, a plane parallel to the working contact MB 2 make contact LAB 2 and a working contact LAB 3, which feeds a signaling BAL, the appropriately consists of a combination of a lamp and from a siren .

The circuit arrangement described above works in the following way: If station A asks station B for approval - it can be, for example, a signal system along a railway line, where station A must have permission from station B to forward a train - , the signal switch CA is turned to position 1A. The relay SA picks up because direct current is fed to the line L via the direct current line LsA and the contacts SA 1, LBA 1 and MA 1 , the relay RA picks up for 6 seconds, the inverter GA 60 generates alternating current with the frequency during the same period of time 60 Hz and sends this to the line L, the lamp AS glowing as a result of the closing of the contact SA 4.

In station B, the 60 Hz energy reaches the frequency converter FB 60, whereby the receiving relay MB picks up and, by opening its contact MB 1, the transmission of direct current from B to A is prevented (which would otherwise be possible if the signal switch was CB is in position 2B ). The relay LAB is excited via the closed contact MB 2 by the incoming direct current from A , and the signaling device BA L is switched on by closing the contact LAB 3 . When A ceases to be supplied with 60 Hz alternating current , relay LAB is kept attracted by the direct current from A through its own contact LAB 1. When the signaling character has been observed by A, the siren contained in the signaling device BAL can be switched off by a push-button, not shown in the drawing.

Station B responds to the request from station A by turning the signal switch CB to position 2B, whereby the relay SB picks up, the direct current battery is connected to the direct current line LsB via contact SB 1, and the relay RB for about 6 seconds picks up, the inverter GB 38 generates alternating current at the frequency 38 Hz during the same period of time and transmits it to the line L, so that the lamp BS lights up as a result of the closing of the contact SB 4.

The light coming from the station B 38-Hz alternating current is supplied to the station A, the reception relay MA via the frequency converter FA 38, which attracts, whereby on the one hand, the DC battery in A of the line L is switched off via the open contact MA 1 and on the other hand Lamp AMB is made to light up via the contact LBA 3 , since the relay LBA is excited by the direct current coming from B. If the 38 Hz alternating current is no longer supplied after about 6 seconds, the lamp AMB lights up continuously, since the normally open contact LBA 2, which is parallel to contact MA 2 , is now closed.

It is obvious that several characters can be exchanged between the stations in both directions in the manner described above without going beyond the scope of the invention. This is shown schematically in Fig. 2, where the station A is provided with a step switch CA with several terminals (n-terminals). Any of a transmission device designated GA 1, GA 2 ... GAn can be connected to the line L by means of the step switch. Each transmission device consists of actuating relays, signaling devices and one or more alternating current sources of certain frequencies for the transmission of alternating current power for a relatively short period of time and of direct current power for a longer period of time to the opposite station, which in turn is equipped with a corresponding number of receiving devices FB 1, FB 2. . . FB n is provided. Each receiving device consists of frequency converters, actuating relays and signaling devices for receiving alternating current power with one or more frequencies and direct current power. In the same way, the station B is equipped with a step switch CB with several terminals and several transmitting devices GB 1, GB 2. . . GB n and station A with a corresponding number of frequency converters FA 1, FA 2. . . FA n provided. Both the transmitting and receiving devices can comprise relay-controlled elements or other actuating devices which are arranged outside the stations. In this way it is possible, for example, to make the response of station B to station A's request to forward a train dependent on the condition of the railway line between the stations in that one or more transmission devices GB n are dependent on the positions which are occupied by the track relays, which are arranged along the railway line and are operated by the passing trains.

Claims (1)

Claim: Circuit arrangement for railway signal systems for the transmission of characters between two stations via a two-wire line, both stations being set up so that they can serve either as a transmitting station or as a receiving station, and are each provided with one or more AC power sources that last for a short period of time Generate alternating currents of certain frequencies and supply them to the two-wire line in order to produce a circuit in the receiving station corresponding to the character to be transmitted, this circuit being maintained by means of direct current generated in the transmitting station, characterized in that the direct current power is generated simultaneously with the alternating current power, that a relay (LAB ) connected to the line (L) via a contact (MB 2) is excited by the alternating current in the receiving station, which prevents direct current from the receiving station via the Leitun via its contact (LAB 1) g (L) is supplied to the transmitting station, and which remains excited by the direct current from the transmitting station, further that the direct current circuit is interrupted by the alternating current generated in the receiving station in the transmitting station in such a way that the alternating current in the transmitting station causes a the line (L) is excited via a contact (MA 2) connected relay (LBA) which prevents direct current from the transmitting station to the line (L) being supplied via its contact (LBA 1). Considered publications: German Patent Nos. 659 031, 678 993, 718 792, 905 985, 850 629; Swiss Patent No. 153 057; Book by Stäblein: "The technology of telecontrol systems", Verlag R. Oldenburg, Munich 1934, p. 227, figs. 102, 99 and 105.