DE872514C - Distribution arrangement for the transition from start-stop to synchronous operation and vice versa - Google Patents

Description

Distribution arrangement for the transition from start-stop to synchronous operation and vice versa The invention relates to a distribution arrangement for the transition from start-stop to synchronous operation and vice versa. The invention is an improvement of the arrangement according to the patent 730 348.. The subject of the main patent is a distributor arrangement of the type mentioned above, in which the synchronous distributor also transmits the start-up and blocking steps or pulse combinations via the synchronously operated line. According to one embodiment of the main patent, the synchronous distributor can be equipped with only one segment per channel. The arrangement according to the main patent is simplified for this case according to the invention id by @ that in place of each. Segment is used by a control frequency controlled distribution relay and the incoming start-stop signs before being fed to the contacts of the distribution relay. be brought into a certain phase position to the control frequency.

Exemplary embodiments of the invention are shown in FIGS.

Figure i shows an equalizing transmitter performing the task at the same time @ de @ s start-stop and the feeder distributor according to the main patent takes over. the -Fig. 2 represents the transmission side. of a dual transmission system, its contact diagrams are shown in FIG. The Fig. Q. and 5 show the corresponding receiver side. The Zig. 6 and 7 show the transmission side and contact diagram of one. Triple distributor, while FIG. 8 shows the associated receiver. Another embodiment FIG. 9 shows the transmission side of a three-way distributor: its contact diagram is shown in Fig. io @. -The equalizing transformer shown in Fig. I forms a component of all transmission systems described below and is therefore described separately so that it can be used in the following exemplary embodiments only needs to be indicated schematically. --.This. equalizing transmitter synchronized the incoming springwriter characters. To produce the scan, a constant oscillating clock used. The alternating current network can be used for this purpose. The control frequency of 50 Hz affects two polarized relays K i and K: ä. Of these Relay, the relay K 2 has two windings I and II, of which the winding II via a .ein-. standing resistance is short-circuited. This makes it possible move the response time of relay K: 2 compared to relay K i so that that it -for example- one. Quarter period compared to the relay K i delayed is. The contacts K i and K2 are designed as changeover contacts and oscillate : when applying the mains frequency in their rhythm between the assigned to them Mating contacts. As a result of the phase shift between the two relays `= lays down first the contact k z to the upper mating contact, shortly thereafter (the current path to close at the bottom contact. The same process takes place with contact k 2 at a later time by the phase shift.

If a start-up step is received by the receiving relay ER, it shifts to the character position so that the relay H responds. This relay has such a response delay that the arrangement described below carries out a center scan of the received pulses. The contact hi is closed, so that a Stromkrens for the relay 1V1 i is created, which has the following course: - TB, contact er, contact h i, contact ki or contact k 2, one of the relays R i, R 2, R 3 to R q., One of the contacts 2, .1, rii, r LLI, r 3i, one of the contacts r 32, r i2, one of the contacts r 42 and r 22, M i, selector arm WA i, C i , Earth.

Which of the above-mentioned paths is chosen depends on it; at which mating contact ki or k 2 lie first after the closing of the -h i contact. Assume. that the contact ki is the first after the closing of the h i-contact at its upper contact. Then the circuit goes through the relay R i and the contact r 2i. This relay responds and opens its contact r ii and r i2, so that the current path for the relays R 2 ) R 3 and R q. is separated. and by 'the subsequent shifting of kz and k 2 can no longer be influenced. For the character just received, only the current path via R z is effective, while the others remain disconnected.

As can be seen from the above, speaks at the start-up step is, initially Idas relay M i. This closes its contact m i and excites thereby the voter magnet W i, which advances the voter one step. Welrn the next step of the step group arrives, the voter arm WÄ i opens: the second contact of the series of contacts, so that the capacitor C: 2 is charged. Simultaneously M i is excited again and the voter is switched to - one step. In this Way are sequentially the seven steps of the sign in the capacitors C i to C 7 stored.

As soon as contact k 3 closes after a pulse has been stored in capacitor C i, capacitor C i is discharged via selector arm WA 2, relay M: 2, relay SR, contact k 3 to earth. The relay 1V12 is energized - and closes its contact m2, which briefly applies voltage to the voter advancing magnet W2, so that the voter arm WA 2 is switched one step further. When the contact k 3 closes, the relay SR is excited by the capacitor discharge, and its contact sr remains on the corresponding contact, that is to say on the sign or isolating contact of the telegraph battery, until the next current surge occurs. The point in time at which the SR is switched is determined by the contact k 3. The polarized relay K 3 is connected to the same control voltage as the relays K i and K 2, so that at the output of the equalizing transmitter the incoming steps of the contact group including: des starting blocking step occur in an equalized manner. - They are brought into a very specific phase relation to the control voltage of the relays K i to K 3 or, in other words, are coupled to this synchronization frequency: The relay K3 has two windings I and II, of which the winding II is on DC voltage is present. The purpose of this is to make the relay K 3 insensitive to the half-waves in one direction of the alternating control current, so that it closes once per period of the alternating current of 50 Hz. It follows that the characters are passed on at a control frequency of 50 Hz at a step speed of 50 baud.

In Fig. 2, a two-flat system is now .darstellung, in which the equalizing transducers EZ i and EZ 2 of the type shown in Fig. I are used. The subscriber T i reaches via ER i; EZ i, SR i the contact vr of the distribution relay VR. This relay VR is also based on the control frequency of 50 Hz: controlled round switches twice per period. In the first period the lead coming from the subscriber T i is connected to the line closure circuit LA of the long-distance line FL , in the second period the lead coming from the subscriber T 2 echoed. In this way, a step of the transmission of the subscriber T i. And a step of the transmission of the subscriber T 2 are given alternately on the trunk line FL.

The contact closure times are shown in detail in the diagram according to FIG. 3. In Fig. 3a, the sampling moments of the relay K 3 in Fig. I are shown: every 2o .ms a sampling takes place. In ider Fig. 3b it is shown how a character arriving from subscriber T i, for example, is passed on through contact sr i. Of relay SR i. will. The character inserts correspond exactly to the scanning moments of the relay K 3. The same process is shown in (the Fig. 3c for the transmission of the subscriber T.2 and the contact sr 2. It can be seen that the two transmissions to each other in any phase position but both are synchronized with the sampling time points of K 3. Fig. 3d now shows the contact of the distribution relay VR. The relay operates with twice the number of oscillations of the relay K 3 and sets in accordance with the circuit of Fig. 2 for 10 ms sr sr contact the contact 2 to the line i and for the next FL io ms. This results in the trunk circuit FL the characters shown in Fig. 3 e, the b from the finger. 3 give to 3 d.

The circuit according to FIG. Q is on the receiving side. met. The characters come from the long- distance line FL via the line terminating line LA to the line receiving relay ERZ. The contact er i is alternately connected to the receiving relay of the subscriber lines ER 3 and ER q through the contact vr of the distribution relay VR, which is designed as a central position relay. placed. The relay VR is again influenced by the same synchronization frequency which is transmitted to the receiving station on some path that is separate from the trunk line. The relay VR is expediently energized, the capacitor C, so that it briefly changes the direction of the alternating control current to one side or the other. For phase rotation, ie to adapt the phase position of the alternating control current to the phase position of the incoming characters, a phase-rotating network N is provided, which is set to the correct value once when operation is started.

FIG. 5 now shows how the characters arriving from the line are fed to the individual subscribers T 3 and T ¢ through the distribution relay VR.

FIG. 5 a corresponds to FIG. 3 e and represents the characters arriving from the line. According to FIG. Q. sets the relay VR in. a short instant, which is set by the phase-shifting network as close as possible to the middle of the incoming impulses, briefly to the separating and character position. As a result, the relay ER 3 or the relay ER q. connected to the contact er i. Depending on the position of the armature, he i sets the relay, ER 3 or ER q. on separating or character position over and remains in this position as long lie! to the next flipping the relay VR another polarity is applied i through it. While the characters arrive from the line at a pace of 100 baud, characters of 50 baud arise for the two subscribers in accordance with FIGS. 5 c and 5, d, and FIG. 5 c represents the characters. represent that to subscriber T 3. by the receiving relay ER 3; are sent, while FIG. 5 d shows the relay ER q. represents sent characters.

6 shows a three-way distributor, the structure of which is the same with respect to the subscriber line. Instead of a changeover relay as a distribution relay, however, three distribution relays VR i to VR 3 are provided, which are each controlled by a special contact of the three control relays R i, R 2, R 3 j by the synchronization frequency. The phase position; the changeover times of the relays R 2 and R 3 can be set by means of resistors, via which a second winding is short-circuited, with respect to the changeover times of the relay R i. The relays VR i to VR 3 are each briefly energized via capacitors C i to C 3 for the scanning. Each of these distribution relays has a second winding. These windings are connected to a DC voltage via a resistor in order to determine the sampling duration. With each change in the direction of the current, the relays VR i Ibis VR 3 respond one after the other, each offset by i2o °, and close their associated contacts. This contact is shown in Fig. 7. During a current step of 20 ms duration, the three relays each close once. So, one after the other, those from. the participants T i to T 3 incoming characters placed on the Senderelais.SR, which they gilbt one after the other via the line closure circuit LA on the trunk line FL . On the long-distance line, impulses of three times the step frequency will occur.

In the receiving circuit shown in FIG. 8, these characters come from the trunk line FL via the line terminating circuit LA to a receiving relay ER i. At the receiver control relays R i to R 3 and distribution relays VR i to VR 3 are provided in the same way as for the transmitter, which successively the current paths to the receiving relay ER q. to ER 6 of the participants ° T q. close to T 6. Since the polarized relays ER q. until ER 6 remain in the position once they have been set as long as they are not excited in the opposite direction, step groups are again sent to the participants at a walking speed of 50 baud.

Another option for the transmission point of a three-way distributor is shown in Fig. g. The. Contacts of the distributors: lerrellais @ VR i to hR3, the again in the manner described above at the control frequency of 50 Hz and their response times by pre-excitation via a second winding by i2o ° each are offset from the previous ones, are in a kind of cascade connection arranged.

In the circuit, the contacts are shown in the position in which they are, according to FIG. 10, shortly before the point in time ti is reached. As shown in the diagrams Fig. Ioax zob and ioc, the contacts are located. vr r and vr 2 in this position at their upper contact, while contact vr 3 is at its lower one. The transmission relay SR is, as described in Fig. Od, connected to the transmission contact sr i ides subscriber T i. At the moment t i, the contact vr i changes over to its lower contact, so that there is now a connection to the contact sr 2 of the subscriber T 2. If at time t 2 the contact vr 3 moves into its äbere position, nothing is changed in this connection, rather the transmission contact sr z mixes remains connected to the transmission relay SR. Only when at: time t 3 .the contact vr 2 flips down, there is a connection from sr 3 via vr 2 ürnd -vY 3 to the transmitter relay SR. Nothing changes about that; if at time t q. vr i do it again upstairs. Rather, the send contact sr i of the subscriber T i is only switched on again to the send relay SR by switching vY 3 downwards at time t 5. This remains so until time t 7, even if at time t 6 vr 2 flipped upwards so that the 'starting position was reached again. The processes described are repeated continuously, and through the contacts vr i. #bis vy 3 the participants T'i Abis T 3 are continuously connected to the 'transmitter relay SR. The one in fing. The circuit shown has the advantage that interference cannot arise due to overlapping of the relay transition times. In addition, two polarized relays are saved. By switching one of the distribution relays in the middle of the current step given by the currently sending subscriber, this transmission is briefly interrupted, but this happens in the middle of the step, so that this interruption has no effect on the position of the transmission relay SR.

Claims (1)

PATENT CLAIMS: -i. Distribution arrangement for the transition from start-stop to synchronous operation and vice versa, in which the start-up and blocking steps of the pulse combination over the synchronously operated path with are transmitted, according to patent 730 348 # and in which the synchronous distributor per channel has only one segment, characterized in that instead of each segment used by a control frequency controlled distribution relay and the incoming Start-stop signs in front of their feed to the contacts of the distribution relay in a certain phase relation to the control frequency are brought. z. Arrangement according to claim i, characterized in that @ that the start-stop characters by one of the same Control frequency controlled scanning device scanned and possibly stored before they are fed to the distributor contacts. 3. Arrangement according to claim ä; characterized in that with a three or more brook distributor the contacts of the various distribution relays in a cascade circuit, such that while a step is being sent by a participant. the path for the control of the transmission relay by the following subscriber through a contact of a distribution relay is being prepared.