DE903346C - Device for reciprocal signal transmission in railway safety, especially for railway block systems - Google Patents

Description

Device for the mutual transmission of signals in the railway safety system, especially for railway block systems, block devices for railways must have a high level of security against interference by external current, since the block apparatus otherwise address at the wrong time and dangers for the trains running on the route can arise. It is therefore common practice to remove those parts of the block facilities which bring about a closure to prevent operations hazardous to the business, to train so that the release of the closure from a remote location can only be done by a certain larger number of current pulses. In today usual block devices produce inductors of alternating polarity and pulses move the tooth segments step by step in the block fields, which only after Taking a certain number of steps to release the locks. To increase In order to protect against external current, block systems have recently also been built in which the Block fields can only respond if they alternate current impulses over two different lines flow. The current flowing during the pulse duration can be a direct current or an alternating current that is generated before entering the Block field is rectified. Instead of the block fields, the tooth segments of which are in move in two directions, step switches are also used in newer systems, in which the organ causing the closures makes a rotary movement in only one Direction executes. While in the systems working with block fields at least two Block fields are operated simultaneously, one of which is at the location of the pulse transmitter into the locked position, the other brought into the release position at the remote location has only been proposed for the systems that work with step switches bring about the release position by a certain larger number of current pulses.

It is also endeavored to train block devices so that they can be operated with as few lines as possible. So is it z. B. desired, in a double-track railway, the blocking processes for both Transfer directions of travel through the same line. Such systems must but not only be safe from interference, it must also be ensured that the currents flowing in the system when it is blocked, even in the event of a line break, line contact, Earth fault or the like never cause an unintentional activation of the block apparatus can.

It is known to use alternating currents of different frequencies for this purpose to use, to sift out at the receiving point by electric switches and the each relevant part of the block device to be supplied. Furthermore, one has suggested alternating current for one direction of travel and direct current for the other to use and the currents at the receiving point through a capacitor and a choke to separate. It is also known to use direct current sources of different polarity for the multiple use of block lines, whereby one is polarized by flow control valves or Relay supports the operationally dangerous current or does not have an effect lets come. Another suggestion for multiple use of block lines goes to a block process initiated by hand or by the train initially to save and only then let it run after it has been checked that no another blocking process is taking place at the same time.

The invention offers a new, simple method for mutual Signal transmission on only one line or a line system between two or several spatially separated stations. For this purpose, a switching device is installed on each station provided that when sending in certain, different from station to station The sender and the receiver alternate with the line or connects to the pipe system. This measure allows each individual station to with the emission of a signal, e.g. B. to start blocking, independently whether about the same process was initiated on another station at the same time or was initiated shortly before. As a result of the different work cycle of the switching devices receive the recipients of the simultaneously working Stations a sufficient part of the program intended for them without them can inadvertently respond to the signal sent by their own station. The currents emitted during transmission cannot be unintentional, even in the event of line faults Triggering of receiving apparatuses, because when power is given, the own receiving device is always switched off completely. The device according to the invention can together with the known means to achieve external current security, z. B. Pendulum circuits in block systems, with the previously existing level of security against External currents are retained. Furthermore, together with the inventive Establish the already known means for multiple use of the block lines apply, which increases the number of transferable terms. The applicability the invention is not limited to block devices, rather it extends also on systems for reciprocal signal transmission in railway safety systems or in other areas of application, if the systems are subject to similar requirements as are placed at block facilities or in similar operating conditions are present.

1 to 3 show the basic mode of operation using an example of plants according to the invention, namely Fig. 1 shows the circuit diagram of two Block locations A and B. FIG. 2 is a contact diagram of block location A, FIG. 3 is a contact diagram of the block location B. Each block location contains a send and a receiving device. The transmitting device of the block point A consists of the Motor 12 that drives inductor 13, the receiving device from a step switch with polarized magnet system 15. The step switch is activated by a for the present description insignificant process within the block point itself brought into the locked position, later it should be powered by current pulses from the blocking point B can be controlled from into the release position. It is for the sake of simplicity Assumed in the description that a few current pulses are sufficient for this; in the practical execution one will choose the number of impulses to be considerably larger to achieve sufficient safety against external currents. As for the opposite Direction of travel an actuation of the step switch 25 of the block position Bin same If necessary, both block locations contain the same apparatus. they wear in Fig. 1 the same designation, but with a different first digit. Except the broadcast and receiving device is a switching device in each block location, e.g. B. 14, present in the block point A, which is expediently regulated by the inductor 13 Speed is driven and from a contact system, z. B. with smallpox-controlled Contacts or slip ring segments, may exist. The switching device 14 can either with contact 141 the transmitting device or with contact 142 the receiving device connect to line 40. Contacts 141 and 142 must not overlap, so that current from your own transmitter never penetrates your own receiving device can. Since the switching device stops in any position after transmission, are the contacts 112 on a block key that is pressed during transmission and 113 provided that are independent of the position in which the Switching device has stopped, the receiving device in the rest position Connect 15 to line 4o and disconnect the transmitter from it.

From the contact diagrams Fig. 2 and 3, in which a line denotes indicates the closed state of the contact or the current output of the inductor it can be seen that when sending the motor inductor through contact iii or 211 of the block key is put into operation and during a certain, designated with necessary Time should remain in operation, which z. B. by appropriate instruction of the operating personnel or by using a timing relay. Here is the simplicity half assumed that the inductor immediately after switching on with the prescribed Speed is running. If the block key is only pressed on one of the two stations, so the switching device leaves the sending station for the necessary time half of the generated pulses in the line and thus in the receiver of the opposite station reach. During the other half of the necessary time, you are at your own station switched to receive by the switching device to a possibly of to be able to record the outgoing signal of the other station. Operate both block attendants their block keys at the same time, each receiver gets the number of pulses also trimmed by the switching device of the own station. Through the different Switching rhythm of the switching devices and the choice of a sufficient value for the necessary time, however, it is ensured that each recipient receives a sufficient Number of pulses received. The worst case is exactly the same Actuation of the two block keys as shown in FIGS. Man recognizes that here the first through sixth and nineteenth through twenty-fourth Impulse remain ineffective, since both stations for the duration of impulses i to 6 A and B work simultaneously as transmitters by closing contacts 141 and 241, respectively and during the duration of the pulses i9 to 24 both receivers 15 and 15 at the same time 25 through contacts 142 and 242 are connected to line 4o. During the For the seventh to twelfth pulse, the transmitter 13 is still on in station A the line 40 switched because contact 141 still remains closed; In the station B, the receiver 25 is switched on through contact 242. The thirteenth through the seventeenth Pulses are sent out from station B, since contact 241 is during this time is closed and the transmitter 23 switches to the line. In station A is at the same time the receiver 15 is switched on by closing contact 142. Stand the two switching devices not in at the beginning of the simultaneous blocking the positions which are assumed in FIGS. 2 and 3, one must choose a different one Place the diagrams in FIGS. 2 and 3 to check the conditions then present think back to the beginning. It can be seen here that in the general case one of the pulses fed to the receiver from the switching device at the receiver's location is cut in two and therefore does not operate the receiver.

Furthermore, the first pulse that reaches the receiver can be full Length remain ineffective because the armature of the polarized magnet system 15 or 25 is already in the position in which the impulse would like to bring it. This Loss of two impulses can occur each time at the beginning of the reception of a contiguous Pulse series occur. It is therefore beneficial to use the one necessary to trigger the receiver Subdivide the number of pulses as little as possible, d. H. the switching frequencies of the switching devices to choose as low as possible. The necessary running time of the transmission facilities is furthermore least if during a half cycle of the slower switching device One or more full periods of the faster switching device expire. Under a period is understood here as the time that passes from the moment of changeover, until the switching device in question does the same switching in the same direction repeats it if the run is not interrupted. So the number of periods is expedient per running time equal to i for the slowest switchover device, for the faster one Select switchover device equal to 2. But you can also do so within the necessary Allow several switching periods for the slowest switching device. Further the time periods for sending and receiving do not have to be the same, and the switching frequencies of the switching devices can be in any other Stand in relation; It is only essential that they are different and that the necessary one The running time is chosen to be sufficiently long. In determining this time for a The system that is to be carried out in practice becomes the number of pulses required for triggering another surcharge to compensate for the impulse loss described above and for make any speed deviations of the switching devices; besides, one will also the total running time of the transmitting devices, e.g. B. to compensate for start-up times, choose something larger than theoretically results.

FIG. 4 with the contact diagrams of FIG. 5 for block point A and FIG. 6 for block point B shows an application example of the invention on a block device for a four-track line in the so-called pendulum current circuit. In this circuit, which offers increased protection against external currents, the changeover switch 145, 146 alternates the direct current generated by the converter 12, 13 on the lines 41 and 42, so that the coils of the step switches 25 or 26 are alternately excited and thereby move the switching element further. The block processes for the two pairs of tracks are differentiated in the present example on the sending station by different polarity of the generator 13 or 23 and selected on the receiving station by blocking cells 251, 261 or 15 i, 161 for the associated receiver. The corresponding polarity, e.g. B. the generator 13, happens through the starting relays 17 and 18. Pulls z. B. on relay 17, it applies the positive pole of the generator to earth via contact 174 and connects the negative pole via 175 and contact 183 of the relay 18, which is at rest, to the line. When the relay i8 is actuated, the reverse polarity is applied to earth and wire through the symmetrical circuit. The switching device driven by the converter 12, 13, which alternately separates the entire transmitting and receiving device from the line system, consists, for. B. at the block point.-I from the two changeover switches 141, 142 and 143, 144. In order to obtain security against incorrect influences, the changeover switches are designed so that 141 and 143 open before one of the contacts 142, 144 is closed. With the changeover device 141 to 144, the changeover switch 145, 146 for the pendulum current can be structurally combined, so that there is a compulsory operation in the actuation sequence of these contacts and therefore a sent pendulum current pulse can never be cut by the switching device of the own station.

In Fig. 4, for example, there is an improvement over the system shown in Fig. i, the automatic shutdown of the switching device itself exists. This makes it possible to use the contacts 112 and 113 or 212 and 2i3 of FIG. I should be omitted, since the switching device is always in the same position stops and therefore the connection of the receiving device itself when it comes to a standstill and can switch off the transmitter. One could use the switching devices, which always begin their course from the same basic position, so build that they be on reception during their first half period. But then needs during this Half-cycle of the converter or pulse generator does not run because pulses are not sent will. It can therefore in each switching device the first half cycle on the necessary time can be saved, so that each station starts transmitting immediately. The prerequisite here is that the block attendant does not perform two operations immediately one after the other. The effective operation of the block key can be known to Make the type dependent on the passage of the train and thus with a double-track Put the switching device into operation twice in immediate succession impede. In the present example of the four-track line, this can be done by corresponding Instruction of the block attendant or by an additional switching measure, which is here is omitted as insignificant.

The switching processes when starting and stopping the converter and of the switching device are briefly explained for the block point A, starting relay 17. When the train coming from the right on the relevant track passes, it closes the contact i i i i. The block attendant switches the relay with the block key ioi 17, which starts the converter with 172 and its self-closing contact 171 closes. The converter starts to run and the switching device overcomes 147 the relay 17 is independent of the block button, which the block attendant will now release can. After the start-up process, the switching device disconnects with the contacts W. to 14.4 the receiver from the line system and attaches the transmitter to it. To the necessary running time, which here is only half a switching period of the device i and 2, it separates with 147 the relay 17, which is now with 172 stops the converter. Through the contacts 142 and 144, the receiving device is at the same time been reconnected to the line. The contact is during the converter cycle i i i i have been opened automatically, so that switching on again only after Passage of the next train is possible. In the block position B play with each other Pressing a block key starts the corresponding processes, but here is the runtime the switching device larger, since the first missing half period is only half as much long is like the block post .- ?.

Another improvement of the facilities described, which the receiver also prevents the response to external currents via insulation faults of your own transmitter would protect the grounding of the contact points i42 and 242 in Fig. I and 142, 144, 242, 244 in Fig. 4, as soon as the associated mating contact of the relevant switch is closed. The grounding would be through additional To effect contacts of the switching device.

The concept of the invention can also be applied to systems with more than two use stations connected to the same line. It is only necessary for this to ensure that stations located on the same line never use the same Use the switching frequency of the switching device and that the necessary times accordingly should be chosen based on the above considerations. The most clear are the relationships if the switching frequencies of the individual stations such as I: 2: 4: ... are selected.

Claims (14)

PATEN TANSPUCIIE: i. Device for reciprocal signal transmission in railway safety systems between two or more spatially separated stations, each of which uses the same line or the same line system for transmission and reception, in particular for block systems working with current impulse sequences, characterized in that a switching device (14, 24 ) in a certain rhythm, which varies from station to station, alternately connects the transmitting (13, 23) and receiving devices (15, 25) with the line (4o) or the line system, in order to enable each station to transmit one Signal can begin regardless of whether the same process is initiated on another station at the same time or has been initiated shortly before, the setting time of the transmitting devices is so long for each actuation that the receiving devices of the opposite stations are sufficient for the intended effect Receive part of the broadcast n. 2. Device according to Claim i, characterized in that the switching device (14, 24) with the impulse transmitter (13, 23) of the own station inevitably in this way is coupled so that switching takes place only between two current surges. 3. Device according to claims i and 2, characterized in that the Changeover contacts (141, 142 or 241, 242) of the switching device (14 lrrw. 24) are not cover. 4. Device according to claims i to 3, characterized in that that in systems with pendulum current (Fig. 4) each line (41, 42) a changeover contact (141, 142, 143, 144 or 241, 242, 243-, 244) assigned to the switching device and that both changeover contacts switch at the same time. 5. Set up according to the Claims i to 4, characterized in that the switching device is the receiver short-circuits as soon as the transmitter is connected to the line. 6. Establishment according to claims i to 5, characterized in that the time segments during which the transmitting and receiving device with the line or the line system be connected, are of the same length. 7. Device according to claims i to 6, characterized in that during a half cycle of the slowest switching device one or more full periods of the faster switching devices expire. B. Device according to claims i to 7, characterized in that in the on the slowest running switching device, the number of periods per running time of the transmitting device is equal to i. 9. Device according to claims i to 8, characterized in that that on the starting element for the switching device, for. B. on the block key (ii1, 21i), contacts are provided which, when the drive is switched off, the transmitting device by means of contacts (112, 212) disconnect from the line and the receiving device through connect other contacts (113, 213) to the line. ok Device according to the claims i to 9, characterized in that the switching device according to its running time switches off the drive motor of the impulse transmitter through contacts (147, 148, 247, 248) and therefore always remains in a certain basic position. ii. Facility according to claim i, characterized in that without the use of the special contacts on the starting element, the switching device in the basic position is the receiving device through contacts (i42, 144, 242, 244) connects to the line and the transmitter separated from it by other contacts (141, 143 or 241, 243). 12. Set up after claims io and i i, characterized in that the transit time of the transmitting device by a half cycle of the switching frequency is shorter than it is with a switching device would be necessary that does not start its course from a certain basic position. 13. Device according to claims i to 12, characterized in that the running speed the switching device is kept constant by an automatic speed controller will. 14. Device according to claims i to 13, characterized in that the switching device from a contact system with cam-controlled contacts or There is slip ring segments.