DE879254C - Device for multiple message transmission, especially for almost simultaneous multiple transmission of commands, messages, etc. - Google Patents

Description

Device for multiple message transmission, in particular for almost simultaneous multiple transmission of commands, messages, etc. The present The invention relates to a device for the multiple transmission of messages, for example for the multiple transmission of commands and messages in electrical Distribution systems. For the remote transmission of several commands and messages, for example also measured values, one has hitherto continuously used circulating distribution switch that be kept permanently in synchronism by some additional control process. One has already worked with high circulation numbers here, and one has the speed chosen so that the distributors ran so fast that everyone a current impulse assigned to a message to be transmitted is divided into several individual current impulses was hacked up. On the other hand one has for the practically simultaneous multiple transmission of messages, especially in power plants, so-called walk-stand distributors (start-stop distributors) used. Either electromagnetically driven stepping mechanisms are used for this or stepping mechanisms driven by an electric motor are used. In all of these Cases one was forced to use the walk-stand distributor with relatively low speeds to run, as with the electromagnetically driven stepping mechanisms as well as with the motor-driven distributor switches with consideration to stopping one or more times during a cycle from purely mechanical Reasons high revolutions could not come into question. the Continuously rotating synchronous distributors mentioned at the outset allow very high Circulation numbers, however, have the disadvantage that the monitoring of the Synchronism requires considerable effort; usually used for surveillance synchronism requires a special transmission channel.

The present invention now avoids the disadvantages of both known ones Facilities, in that as a walk-stand distributor relay chains use that pass through so quickly that even the shortest character to be transmitted is still reliably transmitted during a single cycle or that this is the shortest Character is transmitted by several individual pulses when it is passed through several times. Appropriate the. Arrangement made so that the walk-stand distributor is also synchronize yourself at every step. Another advantageous embodiment the - invention comes about by the fact that the control or reporting flow signs, for example also current signs of electrical telemetry devices on which them assigned transfer step by a pulse of a certain duration or by a pause of a certain duration between two pulses can be transmitted. In other Way, the arrangement according to the present invention can also be formed thereby that two message characters are thereby transmitted at each transmission step be that both a time pulse and a pause of a certain duration at each Transmission step in the passage of the relay chains at the transmitter and receiver location inserted.

An exemplary embodiment of the invention is shown schematically in the drawing shown, namely Fig. r shows a device on the encoder side, Fig. 2 a those on the receiving side. In the drawing, the relays are always large Letters denotes; identically designated relays with similar switching tasks; - In particular, relays of the same type in the relay chains are of the same size Numbers attached to letters differed; the contacts of the relays are throughout marked with small letters. For the contacts of a particular relay are the letters are always the same, while the number of contacts of a relay goes through Appears. Further markings result from the following Description of the overall arrangement without difficulty. -In Fig.z are G1, G2, G3 etc. the encoder devices; for example remote control, remote control or remote measurement transmitter. The transmission of these individual messages and commands can be according to any Procedure. For example, the measured values after the pulse number or Pulse frequency remote measurement method are transmitted, the commands according to a pulse number method. At the receiving location according to Fig. 2, each transmitter is assigned a receiver, the corresponding ones Recipients are with El, E2 üsw. to Eu. The remote transmission facilities for the commands, measured values etc. are known per se and do not need any further details here to be described. It is assumed that the one serving as a start-stop = distributor Relay chain has just been run through, which means that when the relay Ra responds Relay V3 provided with a drop-out delay has responded, its delay is greater than that of the delay relay V, well after the relay V1 dropped by opening the last contact r.lo becomes the normally closed contact v3 of the delay relay V3 closed again; causing the relay chain to run is stimulated. As a result of the relay V1 dropping out and the contact closing v31 the relay R1 comes to speak, according to the following current path: Negative pole, winding z, 2 of R1, normally closed contact u2Iu, normally closed contact v31, normally closed contact vlIIu Series connection of the normally closed contacts zr1IIIo, r2IIIo zy2IIIo to zy3IIIo plus pole of the Voltage source.

If R1 has responded, the relay ZR is excited because its response circuit is now closed: negative pole, winding i, 2 of ZRl, workcontactyllu, rest contacts r2IIIo biszy3IIIo, plus.

After ZRl has tightened its anchor, it holds itself bridging the work contact yllu with his own work contact zylIIIu and separates the relay R1 from voltage by opening the normally closed contact zyIIIo that is now falling off again. The chain now continues in the same way. each relay is energized by the previous one and lasts until it is through Response of the following relay is disconnected from the plus of the voltage source. That Relay ZR, but as the last link in the chain, is only excited by R $, but remains not, but drops out when the normally open contact y "lu opens again.

The delay relay V1 is activated from the first holding step (response from R1) until R8 drops due to the parallel connection of the contacts rilo, y2lo etc. up to y31a connected to voltage. Through the series connection of the normally closed contacts zylIIIo up to zy, llIo it is achieved that each chain relay can only respond once. To A new start is only run through the chain after the delay relay has dropped out V3 possible, and since its delay time should be greater than that of relay V1, so the contact vilIu is already closed before the contact vsI closes and This causes the relay chain to run through again automatically only then is stimulated again; if a good ten after the energization of the last relay has passed. By dimensioning the drop-out delay of the relay V3. can cause be that the pause in the passage of the relay chains changed within certain limits can be. The downtime is expediently assumed in such a way that the relay chains in both stations in any case. come safely to the zero position, if they should have fallen out of step as a result of a disturbance.

The receiver is switched over when the first zero pulse arrives made, whereby the following circuit comes about: plus, normally closed contact e2, normally closed contact uali, normally closed contact ql, normally closed contact ei, normally closed contact xr $ IIo, windings z, 2 of the relays U "and Ub, minus.

The relays -U "and Ub respond; firstly, they short-circuit their windings 4.5 through the normally open contact ublI0 to achieve a drop-out delay and, secondly, they prepare the receiving circuits for the telemetry, remote control or telecommunication receivers EI to En Contact uQII, the contact e1 is connected directly to plus via the normally closed contact ql, and fourthly, by closing the normally open contact ubI, the synchronous passage of the selection relay chain R1, ZR, etc. to ZR, as well as the response of the relay U2 by the normally open contact ublIu, is prepared.

The opposite station now sends the first positive pulse to the line given, the armature of the relay P1 is as shown in the circuit diagram turned to the right and the following circuit closed: plus, normally closed contact qI, Contact p1, normally open contact ubI, winding Z, 2 of relay R1, series connection of Normally closed contacts zylIlu, zr2IIu Y3110 to zyBIIu minus. In parallel with R1 ', U2 excited, which after a single response over its winding. 4, 5, normally open contact zs2Ilh changeover contact asdIII holds. Relay Ri is also maintained via the following circuit: Minus, winding 4, 5, normally open contact rill u, series connection of normally closed contacts zYIIIIo, r2IIIo to zrgIlIo, parallel connection of the normally open contacts acbIII and z @ 211u, plus.

Relay R1 prepares relay ZR through its normally open contact rlIIIu, before that when the contact P is placed to the left, d. H. the line current interrupted or a minus pulse is given, responds and through its normally closed contacts zrlIIlo and zrlIIu interrupt the holding and response circuits of the Rl relay. The relaying of the receiver chain continues so that by each Plus pulse, which is given by the control unit on the line, in the receiver an R relay and a ZR relay is energized by each zero or minus pulse. Here Each relay prepares the response circuit of the following and separates the response and holding circuits of all previous relays. The series connection of the normally closed contacts zylIIu to zysllu enables each chain relay to respond only once, i.e. can only perform a half step at a time. By connecting the normally closed contacts in series 2YIIIIo to zY81IIo it is achieved that only the last relay addressed can hold itself.

As already mentioned at the beginning, the position of the minus pulses within the pulse series is characteristic for each stream symbol of a message to be transmitted. If a minus pulse, for example sent by a remote measurement transmitter using the pulse frequency method or a remote control device using a pulse method, arrives at the receiver, not only contact p1 but also contact P2 is switched. If there is a negative pulse z. B. on the second half step, the following circuit is closed: Plus, make contact p2, make contact ecal, make contact Y @ I, break contact Y.Iu, winding x, 2 of the receiving relay El, minus. The relay EI responds and forwards the pulse to the actual receiving device of the respective communication device and drops out again when the chain continues. The series connection of a normally open contact and the normally closed contact of the next but one relay ensures that the response circuit of the receiving relays EI to En can only be closed during the associated half-step.

The selection relay chain of the receiver thus acts like a distributor, which feeds the negative pulses, which are shifted relative to one another in time, to the receiving relays EI to En assigned according to these times of the chain run.

The arrangement can now also be designed so that the individual individual pulses received by the receiving relay EI to Eu are first stored in a known manner and are only used to actuate an operation when the synchronous running of the distribution chains has been checked in both stations. In the embodiment described, such a safeguard is dispensed with, since the distribution chains synchronize each other both at each step and during their idle time, so that a high degree of transmission security is guaranteed in any case. The checking of the synchronous passage could be carried out by the last relay of the relay chain, whereby it would have to be determined, for example again by a pulse with a negative current direction, whether this has fallen to the last half-step. A special test relay would then have to be controlled through the contacts of the last relay.

The re-run of the relay chain can also be made dependent on it that after the relay chains have passed through in both stations from the receiving station described station a special impulse is sent to the donor station. Only in this case, after the relay chain has passed through in the receiving station a changeover relay U2 specially provided for this in the transmitter station for this purpose the reception of the synchronism signal pulse is switched. By closing the normally open contact zyßl0 in the transmitter, the relay U2 is made to respond, which is via his Winding 4, 5 and the normally open contact u211 holds, whereas the normally closed contact v31 in this case can be omitted. In addition, the continuously addressed relay is E, inserted into the line loop by moving the changeover contacts u21110 and 2621o, after the drop of ZR $ in the transmitter again immediately. Quiescent current flows there during the contact v21 was closed during the chain run. E, so remains for the time being addressed. If the equality reporting relay Q speaks in the receiver at, for example, at the end of the run of the distributor in the receiving center is excited, the line idle current is interrupted by the normally closed contact qIII and at the same time a renewed response of the changeover relays U "and Ub by the normally closed contact qI prevented. When the line loop is opened, it falls into the position of the transmitting station designated station the relay E "from, which is through a normally closed contact e9 or more Contacts similar to the contacts of relay V3 cause the relay chains to restart and that responds again after these operations have been carried out, whereupon both distributors be brought through again. So you can see that the restart the relay chains can either be controlled from the encoder station or as last described, from the receiving point, namely 'thereby; the existence a special step monitoring relay EQ is provided in the encoder station, that from the receiving point at the end of the pass to a temporary one Change of position is brought. The distribution relay chains run through very quickly and synchronize with every step. Also, the distributors are in each Cases paused after one run until both again in all cases have reached their rest position. The routing of the distributors happens as before mentioned so quickly that the shortest of a remote control or telemetry facility transmitted stream characters is transmitted at least once. Instead of the mechanical Relays can also use electron or ion relays that are mutually exclusive control as shown for the mechanical relays. This allows the The transmission speed of the walk-stand distributors can be increased even further.

Claims (3)

PATENT CLAIMS: i. Facility for multiple messaging, especially for almost simultaneous multiple transmission of commands; Messages etc., characterized in that the channel multiplication by means of walking-standing distributors that run through so quickly and are only stopped for such a short time, that all stream characters to be transmitted, including the shortest character, at least be transmitted once. 2. Device according to claim i, characterized in that that the walk-stand distributors are synchronized at every step. 3. Establishment according to claims i and 2, characterized in that the walking-standing distributor is synchronous running relay chains consisting of electromagnetic relays or discharge vessels to serve. q., device -according to claims i to 3, characterized in that the individual message stream characters on the transmission step assigned to them of the relay chains are transmitted by time pulses or time intervals. 5. Establishment according to claims i to q., characterized in that at each transferring step two measurement characters are transmitted in that both a time pulse and a Time interval can be inserted at each half step of the relay chain.