DE886019C - Circuit arrangement for telecommunications systems, in particular telephone systems with branch points that can be called optionally and are located on a common line - Google Patents

Description

Circuit arrangement for telecommunication systems, in particular telephone systems with branch points that can be called optionally on a common line The invention relates to a circuit arrangement with a common Branch lines that can be called optionally, especially on company lines., which are used for train monitoring. In such train monitoring systems, the individual branch points through a central point, the so-called train supervisor, optionally called, while the branch points in the latch do not have any connections produce.

In the previously known systems of this type, the power supply of the devices at the ._ @ or branch points is carried out by batteries, which have a not inconsiderable capacity. Such batteries not only require 'considerable initial costs, but they also have to be regularly charged and later on. being repaired. If the batteries are not adequately charged and maintained, the correct operation of the branch points is impossible or at least very much questionable. The object of the invention is therefore to avoid the source of danger which the batteries form. You achieve this by the fact that for the optional call of the branch points from the central point of the current impulse combinations. depending on the branch point to be called, different current surges are sent out and in the branch points synchronously with the current surges of the current surge combination check control relays one after the other over the common line for the type of current surges of a combination. According to a further feature of the invention, the synchronous connection of the control relays of the branch points to the company management is provided by an incentive given by the central office prior to the election via the company management, e.g. B. Alternating Current; initiated, which is stored in the branch points, for example by capacitors.

In this way, apart from the small ones, it becomes even more necessary Dry battery for powering the microphone, any battery at the stations avoided by the company's management. If necessary, you can use the locally fed charcoal microphone can also be replaced by an electromagnetic microphone, which does not require any power supply, and thus no longer needs a battery at the stations.

Figs. I and 2 illustrate an embodiment of the invention, namely the Fig. i shows the central point at the one. End of company management GL and FIG. 2 a branch or subscriber point at the company management. FIG. 2 adjoins FIG. 1 on the right. Only those for that are shown Understanding of the invention is essential for circuit details.

As can be seen from FIG. Loudspeaker connected to the company management via amplifier and fork. The company management can be divided into several sealed off sections, where the individual branches are located. In the central station, a current impulse transmitter is provided for sending out the current impulse combinations characterizing the branch points. In our example, 16 branch points are assumed at the company management; therefore, the burst transmitter sends a combination of four bursts of electricity at a time. inductive direct current surges in different directions. As is well known, four different power surges can be combined to call 24 = 16 stations. If there are 2s = 32 stations on the company line, a combination of five current impulses each must be sent from the central office. The impulse transmitter at the central station essentially consists of a rotary selector with the switching magnet DM and the four switching arms dm 1 to dm IV: The identification of the one to be called. Station among the 16 stations is carried out by the train supervisor by pressing one of the buttons T i to T 16. Only the button Ti is shown with all contacts and connections, while the button T16 is only indicated for the sake of clarity. When you press the T i z button. B. the button contacts T ia to T id and T i e to T i h are closed. Correspondingly, when another station is called, the button contacts a to lz are closed by pressing the corresponding button. As can be seen from FIG. I, the bank contacts 2 to 5 swept by the selector arm dm II are connected to the key contacts a to d; the bank contacts 2 to 5 swept by the voter arm dm I are connected to the key contacts e to lt. The voter arms dm I, dm II are connected to the a- and 'b-wire of the company line. The key contacts themselves are connected to the line Lt i or Lt 2 depending on the current impulse combination to be transmitted and marked by the pressed key. The lines Lt i, Lt: 2 are connected to the output terminals of the secondary side 2I of the transformer Tr. In the primary winding of the transformer Tr, when setting the rotary selector via its switching arm dm I1I, direct current surges are generated, which are transmitted to winding II. The selector Dzn is started by pressing a common key T g. After the first step, it switches over his switching arm dmIV in a self-interrupting circuit with the relays M and N across the bank contacts to the rest position. At the first step of the voter, an alternating current stimulus is sent from the alternating current source WQ via the company line before the actual surge combination is sent.

The branch point Tn i according to FIG. 2 has a local battery-fed station OB, which is coupled via the transformer R to the company line. In the bridge to the branch line there is the AC receiving relay J, which picks up the AC stimulus. A full-wave rectifier circuit GR is connected in parallel to the branch through relay J. whereby also the capacitor Co i through the arriving via the company line. AC power is charged. After the alternating current stimulus has ended, the capacitor Co i is discharged via the relays A, B, C, D. The relays f1, B , C, D have z. B. with the help of parallel-connected capacitors CO2, CO 3, CO 4, different graduated fall times. These are set in such a way that the relay chain sequentially applies the polarized relays E, F, G, H to the company line, synchronously with the incoming over the company line, the current surge combination so that the relay E on the first, the relay F on the second, relay G for the third and relay H for the fourth surge of the surge combination. Depending on the direction of the incoming current surges, positive or negative, the relays of the relay chain E to H switch their contacts or not. The circuit controlled by the contacts e, f, g, h of the relay chain: for the alarm clock W is wired in such a way that the alarm clock W is switched parallel to the relay J in a bridge to the branch line at the station to be called, which is characterized by the surge combination, see above that the ringing stream then sent out by the central office after the dialing only lets the alarm clock of the station called: sound.

The switching operations are as follows: By pressing the key T i at the central point (FIG. I), the branch point Tn i is called. Before pressing the key T i, the common key Tg is pressed. As a result, the previously charged capacitor Co discharges via the relay P. Relay P responds and switches on the rotary magnet DM of the selector via contact pi. The voter takes a step and goes from position o to position i. When the rotary magnet DM responds, contact dm is closed, causing the relays V and 31 to respond. Relay M switches on relay N via its contact m3. Relay 1/1 closes its two contacts mi, m2, whereby the alternating current source WQ is applied to the two wires a, b of the company line via the two switching arms dm I, dm II. As long as the voter is on step i, an alternating current stimulus is transmitted to all branch points via the company management. In these, the receiving relay J responds through the alternating current.

As can be seen from FIG. 2, the relay J switches the Graetz rectifier circuit GR to the branch line via its contacts ii, i2. At the same time, the capacitor Co i is applied to the Graetz rectifier circuit via contact i 3. Via this capacitor Co i is charged by the rectified alternating current.

The transmission of the alternating current is ended in the central station (Fig. I) by the fact that the selector moves from position i to position: 2. This takes place in that after the relay P has dropped out, the rotary magnet DM drops out. Then the relays V, M, N come to waste one after the other. After the relay N has dropped, a circuit for the rotary magnet DM has recently been closed via the switching arm dm IV: -h, p 2, ni, dm IV, DM, -. The rotary magnet DM responds and switches the selector arms from position i to position 2. As soon as the switching arm dm III reaches position 2, a direct current circuit is closed via the winding 1 of the transformer Ty. As a result, a current surge is induced in winding II of the transformer Tr, which is calculated as a positive current surge. After the rotary magnet DM has responded, the relays h,, I7, N respond again one after the other. As soon as relay N responds, contacts ni, n2, to 3 are opened. Contact ni interrupts the circuit for the rotary magnet DM, so that it drops out and initiates the self-interrupter play anew. Contact n3 opens before contact n2, so that the negative induction surge (Fig. Ia) resulting from the opening of contact n2 is not transmitted to lines Lt i, Lt2. Accordingly, only current impulses in the same direction are always transmitted to the lines Lt i, Lt 2. The current direction of the current surges to be transmitted to the company line GL within a combination is determined by the alternating connections of the respective associated contact pairs of the key contacts to the lines Lt i, Lt 2 . Thus, in the selected embodiment, position 2 of the selector DM is set to a negative via the button contacts T i a, T i e , and to position 3 via the button contacts T i b, T if a positive, to position q. A negative induction impulse is given to the company line via the key contacts T ic, T ig and a negative induction shock again via the key contacts T i d, T i lz at position 5. The selector DM is automatically switched to: the rest position, where it stops because the switching arm dm IV finally interrupts the circuit of the rotary magnet DM.

In the branch point Tn i (FIG. 2), relay J drops out after the end of the alternating current stimulus. About contact iq. the capacitor Co i is discharged through the relays A, B, C, D. The relays respond, as a result of which the relay E is placed in a bridge between the communication lines of the company management via the contacts d, c i, b i, ai. The relay is polarized in such a way that it does not change its contact when the first induction surge arrives in a negative direction. After relay A has dropped out, relay F in is connected to contacts d, c i, b i, a2. Bridge between the cores of the company line. The relay is polarized in such a way that it switches its contact to the incoming second current surge in a positive direction. After the relay B 'has dropped out, there is 2 relay G in a bridge between the cores of the company line via the contacts d, ci, b. The relay G does not change its contact on the incoming third current impulse, this time again in the negative direction. After relay C has dropped, relay H is connected via contacts d, c2 in a bridge between the cores of the company line. It does not change its contact on the incoming fourth current impulse, again in a negative direction. The alarm clock W of the station is now on the contacts e i, f 2, gi, h z in the bridge to the branch off of the station.

In the central office (Fig. I) the surveillance officer places after the Dial his call button RT and thus switch the call current source RQ to the company line. As a result, the alarm clock W is made to sound in the branch point Tn i. The call process is over.

The further switching operations are of no interest to the invention and are therefore not described further.

The invention can also be applied to what are known as call eliminator systems use where the participants in the company management by Morse code be called. In this case, a converter must be provided in the central office, which converts the positive and negative induction pulses into Morse code Line and point implemented.

Claims (7)

PATENT CLAIMS: i. Circuit arrangement for the selective calling of branch points of a company line by a central office, for telecommunication systems, in particular telephone systems, characterized in that for the optional call of the branch points from the central office @ current impulse combinations with different current impulses depending on the station to be called are sent out and in the branch points synchronously with the Current impulses of the current impulse combinations Check the control relays (E, F, G, H) one after the other via the company line for the type of current impulses of a combination. 2. Circuit arrangement according to claim i, characterized in that the control relays (E, F, G, H) are sequentially applied to the company line synchronously with the current surges of a current surge combination and come into effect in different ways depending on the type of individual current surge of a combination, whereby a call signal is switched on at the junction marked by the combination. 3. Circuit arrangement according to claim 2, characterized in that for each Impulse of a combination a control relay is connected to the company line will. 4. Circuit arrangement according to claim 2, characterized in that the synchronous Connection of the control relays in the branch points depending on one in front of the Choice of the station to be called triggered by the central office from given incentive will. 5. Circuit arrangement according to claim 2, characterized in that the stations to be called characterizing current impulse combinations of inductively transmitted There are direct current surges in alternating directions. 6-. Circuit arrangement according to claim 4, characterized in that the synchronous connection of the control relay Incentive sent by the central office from a different one from the election surges Criterion, e.g. B. alternating current. 7. Circuit arrangement according to claim 2, characterized in that the impulse transmitter for emitting the impulse combinations at the central point consists of a stepping mechanism (DM) which, started by the selection process, is automatically incremented and sends out the impulse combination characterized by the selection process via its switching arms . B. Circuit arrangement according to claim 7, characterized in that the impulse transmitter gives alternating current to the company line as an incentive for the synchronous connection of the control relays of the branch points at a selector step which is located before the selector steps serving to transmit the impulse combination. G. Circuit arrangement according to Claim 8, characterized in that by the transmitted from the central station. Alternating current in the branch points via a rectifier arrangement (GR) a capacitor (Co i) is charged, the discharge current of which starts the synchronous control device (A, B, C, D) after the stimulus has ended. ok Circuit arrangement according to Claim 9, characterized in that the synchronous control device consists of a relay chain (A, B, C, D) corresponding to the number of current impulses of a current impulse combination and. the relays are excited simultaneously by the discharge current of the capacitor (Co i), but the relays by time delay devices, e.g. B .. parallel capacitors (Co ? " Co 3, Co 4), in which the rhythm corresponding to the current impulse transmission comes to waste one after the other. Ii. Circuit arrangement according to claim 10, characterized in that the relay chain (A, B, C, D) has a further The chain of polarized relays (E, F, G, H) controls in such a way that one polarized relay after the other in the rhythm of the transmitted current impulses of a combination is applied to the company line to check its type.