DE929198C - Circuit arrangement for storing information, e.g. B. in telecommunications systems - Google Patents

Description

Circuit arrangement for storing information, e.g. B. in telecommunications systems In electrical engineering, e.g. B. in telecommunications systems, the task often occurs Store information for a period of time. This is how it is, for example In telephone systems for long-distance dialing it is common to have a series of digits that indicate the desired Mark the goal, save it in a central facility and then your desired one Connection route or, if it is busy, also a detour to a subscriber available to steal.

Storage facilities for such tasks are facilities such as voters, relays or capacitors, their state of charge as a characteristic of the Storage is evaluated. While by the first-mentioned switching means the structure a storage device becomes extensive and mechanically sluggish, has the use of capacitors have the disadvantage that high requirements in terms of insulation resistance the wiring and the dielectric of the capacitors must be placed, since this affects the duration of the information stored.

Attempts have therefore been made to use inductors with an iron core for storage of information to use. Only the remanence of Interest. It behaves over time under the most varied of conditions not weakened. however, the evaluation prepares an en.n; saved, saved information Difficulty that higher only with large circuitry Effort could be remedied. In addition, they must be of the known type of circuit the evaluation organs are very sensitive to the voltage differences that occur.

The invention also relates to a circuit arrangement for storage of information in which the storage elements are reactors with an iron core used and which is less expensive and works reliably. You achieve this by the fact that for each storage of information (yes, no) two inductors are directionally magnetized in such a way that by editing remanent polarization to store the information in a bridge circuit polarized relay connected to the choke coils is affected.

The directional magnetization of the choke coils is determined by pulse-wise, possibly multiple application of different polarity or voltage made of differing power sources. When using two power sources wind the common plus and minus Po1 grounded. For that repeated magnetization for the storage of information there is an inevitably running relay circuit intended.

The circuit arrangement can also be used in a number memory. According to a further embodiment of the invention, several are combined in groups Choke coils one after the other according to the number of digits to be stored Contacts of a relay chain with their output connected to earth potential. The magnetization a group takes place through contacts of a controlled, common to all groups binary relay chain. The choke coils are directionally magnetized here as well.

Also for other circuitry processes, such as. B. the end office marking, the device according to the invention can be used.

The invention is based on that shown in FIGS. 1 and 2 below Embodiments of which FIG. I shows the circuit for a "yes-no" storage and FIG. 2 shows the circuit for a number memory, described in more detail. A. Storage of “yes” information (Fig, I) If “yes” storage is to be carried out the switch Einsp. yes actuated and thus the circuit for one Relay S closed. I. +, Einsp. yes, S (I), - (6o V ").

Relay T is made to respond via contacts of relay S: 2. +, s I, sII, T (I), - (60V ").

In addition, the following circuits for relay F and G are closed: 3. +, sI, bII, dIII, lIV, kIV, F (I), tIV, Wi I2, - (6o P ").

+, s I, b II, d III, i III, l III, f II, k III, G (I), - (6o V "). About the closed contact g I, the storage throttle Dr I is contrary to the desired Direction magnetized in the following way.

5. +, Dr I (I-6), switch arm a / W, d I, g I, e I, Wi 5, - (6o V ").

The replica throttle also receives NDr contrary to the desired Direction of magnetization. 6. +, NDr (I-6), d1I, gII, f I, Wi7, + (6o V ').

Relay J responds via contact g III: 7. +, s I, lI, h2 I, k I, g III, J (I), - (6o V "). The relay maintains its own contact i I regardless of contact gIII. As soon as it has responded, contact is made through i III the circuit for relay G is open. This falls as a result of its delay slowly from. The contacts gI and gII open the magnetizing circuits for the Throttles Dr I and NDr. When relay J responds and the relay drops out G the relay K was energized.

8. +, s I, g IV, iII, J (II), K (I), - (6oV "). In this circuit the relay J continues via the winding II, since the electrical circuit is controlled by contact k I for the winding I was interrupted. The relay K is via the contact kz I and Resistance Wi io switched in linen. The contact k IV interrupts the circuit for the relay F, so that it drops out. Now you can use the transferred contact k IV and t III address relay E.

s I, b II, d III, l IV, k IV, t III, E (I), - (6o V ").

As soon as relay E has responded, relay G is activated again.

i o. +, s l, b II, d III, i III, t II, e II, f III, k III, G (I), - (6o V ").

Addressed by the state relay E and relay F dropped out the chokes are magnetized in the desired direction. The circuit for the storage choke Dr I runs through II. +, DrI (I-6), switch arm afW, d I, g I, e I, Wi 4, + (6o V ') and for the replica throttle NDr I2. +, NDr (I-6), d II, g II, f I, Wi8, - (6o V ").

The circuit for relay J is interrupted by contact g IV. The relay drops out. Relay K continues via the resistance Wi Io.

Because relay J has dropped out, the circuit for relay G is interrupted. This falls for the second time with a delay. The magnetization circuits for the storage and afterimage troisis, cil are also separated. Due to the relay G dropped out and relay K addressed, the following circuit is now established for relay L: 13- -I-, sI, g IV, i II, k Il, K (II), L (I), - (6o V ") In, this circuit has a winding II of the relay K looped in, so that this can continue through the Wicl: -lang I as a result of the interruption of the current circuit. Relay L is placed in a holding circuit via resistor Wi i I and contact III, and relay G is energized a third time via contact L III.

I4. +, s I, b II, d III, i III, l III, t II, e II, f III, k III, G (I), - (6o V ").

The addressed relay L is relay E via contacts L. IV and t III held. Via contacts g I, g II and e I (switched), f I (released) the chokes are magnetized again according to circuit i i and I2. Through the Contact g IV, the circuit for relay K is interrupted. Independently of the relay L continues via the resistor Wi i i and contact L II. By Contact k III causes the relay G to drop, and with it the magnetization the chokes ended. A flag is displayed via the contacts of the relays that are still being addressed "Yes" storage is switched on.

I5. +, 1 V, kV, g VI, t V, yes, - (6o V "). As from the previous one Description is evident, wound the storage choke Dr I first of all on solder lug 6 magnetized with - 6o V and then magnetized twice with + 6o V. The replica throttle NDr initially received a + 6o V magnetization on solder lug 6 and then two - 6o V magnetizations. Before the magnetization or after the magnetization, the chokes are via the Resistances fWi i or Wi9 damped. As a result, the induction current can only be very slow subside, which has a positive effect on the remanence of the chokes. Let it be here also mentioned that relay chokes of normal manufacture are used in the circuit.

With the return of the switch Einsp. yes all circuits are deleted. B. Saving "Yes" information For the withdrawal process, it is necessary to switch the Aussp. to operate. This closes the following circuit for relay B: I6. +, Aussp., A IV, B (I), WiTT I6, - (6o l '"). Relay A responds via contact b IV and is held independently via contact aIV. Relay B is held as a function of both contacts The low-resistance holding winding I of the polarized relay P an - 6o V "is applied via the contact aI.

I7. +, P (I), a I, g V, P I, Wi I3, - (6o V "). The contact b I prepares the high-pole winding II of the polarized relay P for interrogation. It will furthermore a circuit for relay D via I8. +, aIII, b III, D (I), - (6o V ") and then relay C is switched via I9. +, aIII, b III, d IV, C (I), - (6o V ") closed.

With contacts d I and d II, the chokes Dr i and NDr are connected to the high-resistance winding II of the polarized relay P and to the resistors Wi 2 and Wi3 switched. In connection with the contact cI and resistor Wi6 a bridge circuit is created produced, by means of which the throttles are queried.

2o. +, Dr i, switch arm a / W, d I, Wi 2, c I, Wi6, - (6oV ").

2I. +, NDr, dII, Wi3, c I, Wi6, - (6o Since the residual magnetism of both Choke is polarized in the opposite direction, there is briefly a for the relay P (II) Response voltage, d. H. Relay P responds and binds itself via 22. +, P (I), a I, b V, p I, H (I), + (6o V '). In this circuit the relay H (I) also speaks on, which binds itself in a circuit in which also relay T to respond comes: 23. +, a II, lII, h II, H (II), T (I), - (6o V "). Relay H remains through the Response of the relay T still excited via the winding I. By addressing the Relay C is short-circuited via contact cIII to relay B (I). It falls off. A repeat response is made impossible by contact b IV. Through contact b I the high-resistance winding II of the relay P is switched off. Contact b III interrupts the circuit for relay C. Due to the dropped contact c II, the relay also drops D. This means that the query circuits for the chokes are also interrupted. In connection the throttles Dr i and NDr are activated by an automatic “yes” storage in their initial magnetic state. Instead of the contact s I appears the contact a II of the still addressed relay A. The processes play out in in the same way as described under Section A. After the first response of relay G, the circuit for relays P (I) and H (I) is interrupted. Will the switch Aussp. put in the rest position, so are all existing circuits turned off. During this process, the indicator "yes" appears again. I C. Store "No" information. With a "No" input, the switch Einsp. no actuated. In a similar way to "Yes" storage, the same circuits closed. Relay T, however, cannot respond as the contact sII remains open. The relay F speaks in series with the Relay E on.

+, Einsp, no, b Il, d III, I IV, k IV, F (I), tIV, hIII, E (I), - (6oV "). This triggers the following additional circuits. Relay G speaks an over 25. +, Einsp, no, b II, d III, i III, L III, f II, k I II, G (I), - (6o V ").

The storage choke Dr i is then magnetized in the following direction: 26. +, Dr i, switching arm af W, d I, g I, el, Wi4, (6o V ').

The Nachbi.ld@dr olssel NDr receives the following magnetization: ung 27. -I-, 1V Dr, d11, gII, f I, Wi7, -f- (6o V '). Relay T responds via $ 2. -E-, Einsp. no, II, hl, k I, g III, J (I), - (6o V "). The relay maintains itself via its own contact i I. Contact i III interrupts the circuit for relay G. This re-activates the chokes When relay G drops out, relay K is actuated and, at the same time, relay J is held in this circuit via winding II. Contact k IV opens the circuit for relays E, F, which drop out renewed response of relay G.

29. +, Einsp, no, b II, d III, i III, t Il, e II, f III, k III, G (I), - (6o V ").

With the contacts g I, g II closed, the chokes are again magnetized. The following circuit 3o results for the storage choke Dr I. + Dr I, switching arm a / W, d I, g I, e I, Wi 5, - (6o V ") and for the replica throttle 3I. +, NDr, d II, g II, f I, Wi 8, - (6o V "). Contact g I V creates the circuit for relay J interrupted. Relay K continues via winding I. The contact i III in turn interrupts the Stromkrens for relay G, and thus becomes the magnetization of the chokes ends. Via the dropped contact i II, as described in section A, the relay L is now made to respond. After its actuation, relay K is held by winding II. Relay L lies down via the resistor Wi II and contact lII in a holding circuit. About the contact lIII relay G is made to respond again and the throttle after the circuit 3o and 3I magnetized again. Contact g IV brings the relay K zem waste, whereby again delayed by contact h III relay G drops and the magnetization of the throttles is interrupted by the contacts gI, gII. Relay L is held. About 32. +, LV, kV, g VI, t V, no, - (6o V ") speaks for this storage command provided indicators.

In the case of a “no” storage, the throttle Dr I is on the soldering lug 6 first once with a voltage of + 6o V and then twice magnetized with a voltage of - 6o V. The replica choke NDr is attached to solder lug 6 first one + 6o V - and then two - 6o V magnetizations.

By resetting the Einsp. no will all circuits turned off.

D. Saving a "No" information During the saving process "No" speaks by turning the switch Aussp. the relay B and subsequently that Relay A on. The contact aI in turn switches the winding I of the polarized relay P an - 6o V ", and contact b I prepares the circuit for winding II of the polarized relay P for interrogation. As described in Section B, the relays D, C operated. Since now the storage throttle DrI and replica throttle The polarized relay in the bridge circuit can have the same magnetic polarity do not address. The other switching operations now follow, which consist of that thrown off by contact c III relay B and thus the winding II of the polarized Relay P is switched off by contact b I. The contact b III interrupts the Circuit of relay C, as a result of which relay D also drops out. With the In contrast to d I, d II, the throttles are completely relieved by the resistances Wi 2 and Wi 3 switched off.

Following these processes, both throttles are automatically activated "No" storage is set to its initial magnetic state. As a mark the relays kept in the energized state serve for this storage Storage facility. Here, too, the indicator "No" appears as an acknowledgment signal. E. Use of the storage throttle with a number memory The number memory (Fig. 2) consists essentially of a relay chain A I to A Io, a binary relay chain N I to N4 and the storage chokes D I to D4o. The storage processes play as follows. First, the relay A I of the relay chain is addressed over 33. +, aIoII, a9II, a8II, a7II, a6II, a5II, a4II, a3II, a2II, A I (II), - (6oV "). A number disk NSch is used to send impulses to relay JM, and this is thereby excited impulsively.

34. +, nsi, TM, -.

The circuit for relay V is closed by contact imI 35. +, im I, V (I), WI9, - (6oV ").

The relay is held by the VI contact during the pulse series. Relays M and W respond via contact vII. During the first pulse the capacitor C I is charged via 36th +, n I II, in II, C I, Wi I2, -. After this Impulse responds to the relay N I due to the discharge current: 37th C I, im II, N I (I), back to C I.

The relay NI is held via the contact n I III and w III and the winding II. With the second pulse, the capacitor is charged in the opposite direction and discharged via the relay NI during the break. Relay NI drops out again as a result. During the second pulse, that is, while the relay NI responded, the capacitor C 2 was charged. Its discharge takes place in the stalemate via relay N2 (I). The binary relay chain N2 to N4 switches according to the circuit described first. It can take up to fifteen pulses and transmit them to the storage chokes on a binary basis. So z. B. the following circuits: 38. +, a I III, D i, either via ni V, W2, v IV, W 9, -f- (6o V) or * i V, Wi, vIII, Wzo, - (6o H").

The storage throttles are analogously via the contacts a22 V bis n4.V magnetized, namely, since Releis A i has responded, the first: Group D i to D4- After: the first I. pulse, sT: the series brings the Contact in I the relay V by short circuit to drop. As a result, the Voltage disconnected from the storage chokes. Via contact vII the relay W (I) short-circuited and, delayed, brought to waste. While the relay M7 still holds a delay, the relay A 2 responds in the following way: 39. +, m I, wII, A2 (I), aI I, aioI, AI (I), - (6o V ").

Relay A 2 is held by a second winding I I 4o. +, a i o II, a9II, a 8 II, a7II, a6II, a 5 II, a4II, a3II, a2II, A2 (II), - (6oV ").

Until the relay M drops out, the relay A i remains in the circuit 39. Contact wIII instructs the circuit for relays N i or N2 to N4. Yet the following pulse series are stored in the storage chokes D 5 to D4o, the latter in each case through contacts of the relay chain A2 to A Io in preparation Earth to be laid.

The previous description has shown how a storage is made in a number memory. The digits can be saved with Help from afterimage chokes in the same way as with a "yes-no" storage be made. The circuit can be particularly advantageous in a testing device apply for ZTG, where a test is only required if the stored Digits do not match the saved digits. Both for storage as well as for the carrion storage, a number each are shown in the test device for comparison Chokes used. A polarized relay is also used for evaluation, that can only respond if the chokes to be compared are appropriate are directionally magnetized. The circuitry processes are similar Way as in the first example described ah, so there is no need here to elaborate on it. F. Use of the storage choke for monitoring and end office marking In the embodiment shown in Fig. I, the soldering lugs i of the chokes Dr i to Drn together with the grounded plus and minus pole of two voltage sources tied together. This connection is separated and relays are placed over switch contacts into the individual cores, this arrangement can also be used to mark the end of the line will. The switching status of one of the relays located in these wires can be used for this purpose to mark a certain point or a certain connection line.

Claims (7)

PATENT CLAIMS: i. Circuit arrangement for storing information, z. B. in telecommunications systems, in which the storage elements are reactors with an iron core are used, characterized in that for the respective storage one Information (yes, no) two inductors (Dr i, NDr) are directionally magnetized in this way that through their remanent polarization for storing the information a polarized relay connected to the inductors in a bridge circuit (P) is influenced. 2. Circuit arrangement according to claim i, characterized in that that the directional magnetization of the choke coils by pulse-wise, under certain circumstances multiple application of different ones, differing in their polarity or voltage Power sources is made. 3. Circuit arrangement according to claim 2, characterized in that that two current sources (6o V ', 6o V ") are used for directional magnetization of the choke coils are provided, the common plus and minus pole of which is earthed. 4. Circuit arrangement according to claim 2, characterized in that for repeated magnetization of the Choke coils for information an inevitably running relay, circuit (J, K, L, T, H, G, E; Fig. I) is provided. 5. Circuit disorder according to claim t or i to 4, characterized in that the choke coils before and after the magnetization short-circuited via resistors (Wi i, Wi9). 6. Application of the circuit for a number memory according to claims i or i to 5, characterized in that several Choke coils combined in groups (D i to D 4 D37 to D4o; FIG. 2) accordingly the number of digits to be stored one after the other through contacts on a relay chain (A i to A Io) are assigned their output to ground potential and the magnetization a group through contacts (n i V to n 4 V) of a controlled, common to all groups binary relay chain is made. 7. Application of the circuit according to claim 6, characterized in that the choke coils via the contacts of the common binary Rel, aiiske @ tte has been directionally magnetized. B. Application of the circuit for the End office marking according to claims i or i to 5, characterized in that several Dro, s, selspule in are connected to relays via contact sets, their windings can be effectively switched on during the marking process and the occupied one via contacts Mark the line on a signaling device.