DE874149C - Arrangement for the triggering of periodic processes by means of control currents, especially for the distribution and comparison of telegraphic characters - Google Patents

Description

Arrangement for the triggering of periodic processes by control currents, especially for the distribution and comparison of telegraphic characters to patent 862 911 In patent 862 gz r is an arrangement for the triggering periodic Processes handled by control currents that depend on a starting criterion, z. B. a tempering step, a certain number of control operations at certain intervals generated. For such arrangements, mainly for distribution, sampling and the comparison of periodic characters is suggested in the main patent, an alternating current oscillating at the same frequency. to the control use, which depends on the starting criterion in any phase position with the to be controlled Links is connected, but its tax effect regardless of the point in time the occurrence of the event criterion only with a following characteristic Phase position of the control alternating current occurs.

The present invention relates to an improvement in the arrangement according to the main patent. It consists in the fact that the control current is alternating current, rectangular Waveform is used, which depends on the occurrence of the starting criterion a winding energized by neutral relays of the distributor, the other winding of which was previously through a Continuous direct current was excited, and that when switching this relay as a result of the change the direction of flow of the control current is the assigned control contact, preferably the distributor contact is actuated. Such an arrangement allows the Use of simple, neutral relays, such as those used in telephony in general are common. While so known distributors with neutral relays either at all have no local control rank or but only relay interrupters; the one for each Characters are specially left on, a continuously continuous one can be used in the invention Control current, namely a square wave alternating current, can be used and still the Relay chain can be operated according to the start-stop principle.

Provided the normal telegraph speed can the square wave alternating current in a simple manner by using a known frequency dividing circuit can be obtained from the alternating current network by halving the frequency. It surrenders then an alternating current of 25 Hz corresponding to the telegraph performance of 5o baud.

Two exemplary embodiments of the invention are shown in FIGS. namely, FIGS. i to 3 relate to a transmitter and FIG. 4 to one Recipient.

The distributor according to the invention consists mainly of relays A to J, each of which has two windings. The relays are dependent on one another in a known manner and switch one another on. The W icklüpg I of these relays has a permanent DC excitation which can be switched on and off via the relay contacts shown and which is generated by the battery B. An alternating current, preferably rectangular in shape, of 25 Hz, for example, is fed to the terminals RW. But you can also achieve a non-uniform progression of the relay chain by alternating any composition, e.g. long and short, used one after the other and thereby progressing the distributor. These changes supplied via the terminals, RW are made via relay contacts, their. Operation will be described below, the windings II of the above-mentioned relays A to J supplied. These relays respond one after the other and switch their contacts. Be there. the transmission contacts, which are in the line circuit shown on the right with the terminals L i and L: 2, opened and closed one after the other. In the event that a normal teletype transmitter is to be operated in the manner proposed, the keys actuate the contacts T i and T 5 in accordance with the step groups of the alphabet used, for example the five-letter alphabet. When a key is pressed, certain contacts T i to T 5 are open and others are closed. At the same time as the contacts, T i to T 5, the contact AT is also closed, which causes the relay K to respond. And thus causes the relay chain to start: Instead of a telegraphic button transmitter, you can of course also use a punched tape transmitter LS with the contacts LS i to ls 5, as indicated within the dotted border in FIG. The contact AT must then be closed in a known manner by the switching device of the perforated tape after each scanning process. Instead of a punched tape transmitter, an automatic storage unit can of course be connected, as is provided for example in the case of the known central transmitters. The invention is particularly suitable for such transmitters, which are used, for example, as name givers, time givers or also as givers for the measurement result from veracity measuring devices or the like. The device can of course also be used to send out step groups of any composition and then the contacts T i to T 5 and AT have to be designed as simple toggle switches. which determine the composition of the step groups.

For the sake of simplicity it is assumed that it is one of the usual key transmitters and that the sign + - + - + is to be sent out. Accordingly: when the assigned keys are depressed, the contacts T i, T 3, T 5 are closed, the contacts T 2 and. T 4 are open. At the same time the KÖntaktAT is closed and the relay K is energized. This forms a holding circuit via contact k 3. Contacts T i to T 5 remain in the set position while the relay chain is running; for example, in that the button is locked in the depressed position until the locking step is sent in a known manner. When relay K responds, contacts ki and k 2 are also closed, so that winding I of relay A receives a direct current pre-excitation in a specific direction via k 2. Direct current alternations with a rectangular waveform of 25 Hz for the usual telegraph frequency of 50 tape are fed to terminals WW: accordingly, winding II also receives an excitation via contact b i. This pre-excitation can, according to FIG. 3, start at a point in time ti at which the phase position of the square wave changes just causes the windings I and II of the relay A to be excited in opposite directions. Then the relay A responds shortly after: time t 2, ie after the direction of the change of rectangle has changed. However, the phase position of the rectangular changes can also be just such that the directions of the rectangular changes and the pre-excitation coincide. Then the relay.! I responds at the instant of switching, ie for example at time t 3.

The further sequence of the relay chain is the same for both response cases. When relay A responds, contacts ai and a 2 are closed and the DC pre-excitation of relay B via winding I is switched on via A II. At this moment,. ie at time t: 2 in the first response and at time t 3 in the second response, the excitation in windings I and II of relay B is in opposite directions. So the relay does not respond. Only when the current direction changes at time t ¢ does relay B respond and with its contact bi opens the current path for winding II of relay A, and with its contacts b: 2 and b 3 it closes the current path to the windings. I and II of the relay C, and finally the contact b 4 opens the telegraph line with the terminals L i and L 2, so that the quiescent current previously prevailing on the line is interrupted. This causes the start-up step to be sent. The next time the current direction changes, ie at time t 5, relay C responds in the manner previously described for relay B , since its windings are again wound in the same winding sense as those of relay A. This opens the circuit for the winding with ci II of the relay B, closes the field winding for D with c 2 and c 3 and connects the contact T i with the telegraph line with c 4. Since, as assumed above, T i is closed, a current step is now given to the line following the currentless start-up step, which ends at time t 6 because relay D responds with this change in current direction and contact d 4 the contact ti turns off. The relay chain continues to run in the manner described, and relay E responds at time t 7, relay F at time t 8 , relay G at time t 9 , relay H at time t io and finally at Time tii the relay J. The latter interrupts with its contact i 2 the relay A, which switches off the winding I, with i 3 interrupts the circuit of the square wave change, with i 4 initially creates a holding circuit and with i 5 the relay IL to drop out brings. The latter interrupts with the. Contacts k i, h 2, h 3 again the circuit of the square wave change, the pre-excitation circuit for the relays A to J and its own holding circuit. Now relay J also drops out. As a result, the initial state is restored, and a new cycle of the relay chain and the transmission of a new character can begin.

In FIG. 2, these processes are shown graphically; one further explanation of this figure is therefore unnecessary.

FIG. 3 shows a modification of the transmitter according to FIG. I for double current, and only the changed part is shown. The relay chain remains the same. Here, too, there is no need for a detailed explanation, since the process is exactly the is the same as in Fig. i. The double current send contacts switch each other so that special disconnection contacts are not necessary.

On the receiving side (Fig. 4) the polarized receiving relay Y is actuated by the received characters, which switches with its contact yi according to the starting pulse in the opposite position shown and thereby brings the relay L via the contact r 4 to respond. This relay L corresponds to the relay A of the transmitter relay chain and causes @ t with its contacts ii to 13 to switch on the square-wave alternating voltage at the terminals RW and the battery B, which in turn relays M to R with the windings I and II in the similar to FIG. I excite the manner described and cause the relay chain to run. With the help of the contacts m 3 to q 3 and m 5 to q 5 and r 2, the relays S to X are successively connected to the contact y i. Depending on whether the corresponding pulse was a current or no current pulse or a plus or a minus pulse, the relays S to X are excited or not, namely via the windings SI to X I. They are formed via the windings . S II to X 1I holding circuits with the help of their contacts si to x i. By means of the contacts of these relays, that is to say by means of the contacts s 2 to x 17, the pyramid circuit known per se can now be formed, for example, by means of which one of the circuits St i to St 32 is selected. In the case of a teletypewriter, there will now be a magnet in these circuits which will create the. assigned type lever operated, or in the case of a central transmitter z. B. for a distortion measurement result, a display means for a specific distortion. In the case of the transmission of commands or control commands, the triggering of the relevant switch will be controlled via such a circuit. Instead of the pyramid circuit, the position of the contacts of the relays S to X can of course also be combined in other ways, for example by using magnets instead of the relays to control the five selector rails or disks and thus a pull rod for one in a known manner Select type lever or determine the position of a type wheel rotating with a search pawl.

Claims (2)

PATENT CLAIMS: i. Arrangement for the initiation of periodic processes through control currents, especially for distribution, sampling and comparison telegraphic characters, according to patent 862911, characterized,) ate as control current AC current with a rectangular waveform is used, which depends on the occurrence of the Starting criterion a winding of neutral relays (B to J, Fig. I, and 1J to R, Fig. 2) of the distributor, the other winding previously excited by a continuous direct current was excited, and that when switching this relay as a result of the change in the direction of the current of the control current the assigned control contact, preferably the distributor contact, is operated. 2. Arrangement according to claim i, characterized in that the circuits of the two windings or neutral distribution relays in the manner of a relay chain be prepared by contacts of the respective preceding relay.