DE921458C - Power surge storage, especially for telephone systems - Google Patents

Description

'' Impulse storage devices, in particular for telephone systems in telephone systems with selector operation, surge storage devices are required for a wide variety of purposes. So z. B. in self-dialing long-distance traffic through surge storage, the preparatory, but often unnecessary occupancy of the connection sections from the end office to the distribution remote office (Blind assignments) can be avoided.

As is well known, the current impulse stores take up and store series of current impulses them up to a certain point in time and then give them either converted or the same number, but with the required or possibly a new pulse ratio out again. The invention relates to surge storage devices of the latter type, which are also called pulse repeaters, as they store the stored series of impulses pass on unchanged in terms of numbers. There are surge storage devices of various types known. There are those which take up the series of current pulses in memory selectors and again by one or more tap selectors scanning the memory selectors issue. Other known surge storage devices use mechanical devices, z. B. in the form of a wreath of pins from which according to the number of Current surges and the number of series of current pulses individual selected and included in the drainage path a surge transmitter can be pushed to control its process differently. Furthermore, surge storage devices are known in which the storage device is filled Adjustment of the storage elements in one direction and emptying of the storage by adjusting the same spoke links in the opposite direction. In particular will the Storage elements through forward and reverse gear drives twisted in opposite directions.

Electricity storage systems with several storage areas are also known one after the other, possibly in cyclical order, during an assignment in Be put into operation. The withdrawal of the first series of power surges can take place immediately after the end of the saving process. The Storage units switched on by relay chains or control switches.

In these known memories, the control of the dispensing takes place .the stored current impulses serving switching or storage elements .by current impulse transmitters, which are individually assigned to the surge storage devices. To comply with the prescribed The current impulse transmitters require the current impulse ratio for the current impulses to be delivered a certain circuit complexity, which is with the large number of per office required memory significantly in .the weight falls.

This disadvantage can be avoided if you use the to deliver the stored Switching or storage elements of all current surge storage devices that serve for current surges of an office assigns a common impulse generator, which is responsible for the respective Telephone system required current surge ratio determined. Such an arrangement too is known, e.g. B. by the Austrian patent specification 159 263. This arrangement has the disadvantage, however, that the first impulse is distorted and even falsified, because the duration of the first current surge depends on the phase position of the common, the surge generator forming interrupter: These disadvantages are avoided by the invention in that a continuously working, the pulse ratio of the stored Changeover contact of the common impulse transmitter that determines current surges via its On the rest side when the withdrawal is initiated, the connection of the withdrawal to be carried out Memory element causes and after connection of this memory element on its working page its switch-back magnet causing the transfer of the stored current surges switches on impulsively.

The invention has the advantage that a simple and clear Circuit arrangement with the possible -, venig switching means is achieved. It is only the switching means that are absolutely necessary for reliable storage and retrieval available. Furthermore, through the changeover contact which determines the pulse ratio ensures that no distortions or falsifications of the stored Impulses can occur.

The drawings show an exemplary embodiment of the invention, namely in FIG. 1 the circuit of the memory device Sp assigned to a connecting line is shown, while FIG. 2 shows a memory system M in schematic form. A plurality of such storage systems are assigned to the storage device Sp. As can be seen from FIG. 2, a storage system consists of a cam disk N which is rotated in one direction by the gear Z i and in the opposite direction by the gear Za. The cam disk and gears sit firmly together on the shaft W. The gear Z i is rotated step by step by the push pawl actuated by the forward magnet VA1T, the gear Z2 is rotated step by step in the opposite direction by the push pawl actuated by the reverse magnet RM. As soon as the cam disk has left the rest position shown in the drawing, the normally closed contact is opened: 2 m and normally open contact i in is closed.

The rotation of the cam in one direction and the other can of course also in another way, e.g. B. instead of two separate ones Gears are made by a single gear, which is driven by the forward and reverse magnets is alternately advanced.

The storage device Sp, shown in Fig. I, consists of three storage systems Consisting of Ma, Mb, Mc, is assigned to a power transmission Ue, from which only the circuit details absolutely necessary for an understanding of the invention are shown.

In the description below, the plus sign denotes that in the Usually grounded positive pole, with the minus sign the negative pole of the official battery designated.

When a connection line is occupied, the occupancy relay C (not shown) responds in the transmission Ue. Relay C switches on the selector relay WR by means of its contact ic, which serves as a control switch for the successive connection of the forward magnets hm i, Vrn2, hm 3 of the storage systems Ma, Mb, Mc to the surge receiving circuit. As is known, the selector relay WR represents a small rotary selector which, in the present example, leads the selector arm wr over twelve contacts in the bank contact row. The forward magnet Vm i is attached to contacts o, 3, 6, 9 of the selector relay, and the forward magnet is attached to contacts i, q., 7, ro; connected to the contacts 2, 5, S, 1i of the forward magnet Vzn3. The reverse magnet Rzni, R, »z2, RM3 of the storage systems is a multi-part control switch, e.g. B. assigned seventeen-part rotary selector, which is driven by the rotary magnet D. The reverse magnet Rm i is connected to steps ?, 17, the reverse magnet Rm2 to step 7, and the reverse magnet Rm3 to step 12 of the control switch D, for example. The reverse magnets are connected one after the other to the central pulse transmission contact i via the control switch dI.

The selector relay WR has no distinct rest position. The voter arm wr should be in step 2 before the line transmission Ue is occupied. When the transmission Ue is occupied, the selector relay WR responds via the contact ic of the occupancy relay, as already mentioned. The voter takes a step and moves to position 3. He stops at this position for the time being. Due to the incoming current impulses of a numbered current impulse series, a not shown current impulse receiving relay A is excited in the line transmission, which sends the current impulses to the forward magnet hm i in the following way: -I-, 2 a, 3 g, wr, hm i, -. The cam disk N (FIG. 2) of the storage system Ma is incremented by the current surges. As soon as it is rotated out of the zero position in the first step, the cam contacts i ma, 3 ma are closed and cam contacts 2 ma are opened. During a number current surge series, the delay relay h is energized in the transmission Ue in the usual way via contact 7 a of the surge receiving relay. After the end of the series of impulses, relay h drops out; this energizes relay S in the following circuit: -i-, qv, vm i, i ma, SI; -. Relay S responds and binds itself via contact si: +, si, vm i, i ma, SI, -. Relay h, which had short-circuited the selector relay WR via contact 5 v and caused it to drop, releases the selector relay again after the end of the impulse series. The selector WR takes a step and goes to position q .. In this the current surge receiving circuit for the forward magnet Vm 2 is prepared.

Relay S lets through its contact sq. the central impulse transmitter i. After the relay S has responded, a circuit for the control switch D is also prepared via contact s3. Its switching arms d I, d II are, as can be seen from the following description, before the storage device is occupied on a step immediately following the connection contact of the reverse magnets, i.e. either on step 3 or 8 or 13. It is assumed that the control switch D is on step 13. The central rush current sending contact i works continuously in a fixed rush current ratio, e.g. B. 6o: 40, ie contact ii is closed 6o ms, contact i 2 40 ms. Assuming that contact s 3 is closed at the moment in which contact i2 is closed, the following circuit for the control switch magnet D is closed: -f-, i2, s3, dII (position i3), D, -. The control switch takes a step. The circuit for the rotary magnet D is interrupted as soon as contact i2 is opened. Since the contacts in the contact bank d II of the control switch are bridged with the exception of the connection steps for the reverse magnets, the control switch D is now incrementally advanced by the pulse transmitter until the control switch arm dII has reached position 2 or 17. In this position the circuit for the rotary magnet D is interrupted by the opened cam contact 2 ma. The reverse magnet now receives so many impulses via control switch arm dI in position 2 via contact ii until the cam disk of the storage system is turned back into the rest position: -I-, i i, d I (position 2), 3 ma, Rm i, - . The number of backward steps corresponds to the number of forward steps of the cam disc. The reverse magnet RM i, when excited, sends earth impulses to the line L by means of its contact i rm i. As soon as the cam disk of the storage system Ma has reached its zero position, cam contact 2 ma is closed again, cam contacts i ma, 3 ma opened.

Relay S drops out when the charging of the next storage system Mb is in progress or has not yet been initiated by the next series of impulses (after the first storage system has been discharged). If the storage system Mb is currently being charged, ie if the forward magnet hm 2 is currently receiving the impulses of the second series of impulses, the holding circuit for the winding I of the relay S is interrupted by the contact vm 2, which works in pulses depending on the magnet hm2. The drop in the start relay S has the consequence that the discharge of the storage system is interrupted. Relay S can only respond again when the recording of the current impulse series has ended. Relay S then responds in the manner already described after relay V has dropped via contact 4v. This inevitable interruption of the progress of the discharge has the purpose of avoiding a simultaneous actuation of the forward and reverse magnets with certainty.

In all other cases, when the storage of the emptying leads by at least one series of impulses, relay S remains energized, namely via its own contact si, contact vm and closed cam contact in the charged storage system. It is assumed that the second series of impulses has already been absorbed by the forward magnet Vm2; the cam contacts i mb, 2 mb, 3 mb of the memory system Mb are actuated accordingly. Relay S is energized. The emptying continues by switching the control switch assigned to the reverse magnet, since its rotary magnet D receives a current surge in the following circuit: -h, i2, s3, 2ma, dI (position 2), D, -. The control switch moves from position 2 to position 3 and from there via the wired contacts of the contact bank to position 7. These intermediate steps determine the dialing pause between two series of current impulses.

In position 7 of the control switch, the circuit for its rotary magnet D at contact 2 mb is interrupted. The control switch stops. The reverse magnet Rm 2 now receives current surges in the following circuit each time the pulse contact ii closes: -I-, i i, dI (position 7), 3 mb, Rm 2, -. The magnet Rm 2 sends earth pulses to the line L by means of its contact i rm2 until the cam disk of the storage system Mb is rotated back into the zero position. Cam contacts i mb, 3 mb are then opened, cam contacts 2 mb are closed.

The same switching operations are now repeated as were already described when the control switch D changes from the connection contact 2 of the reverse magnet Rm i to the connection contact 7 of the reverse magnet Rm2. Relay S remains energized or is energized. As soon as the pulse contact i2 closes, the rotary magnet D of the control switch receives a current impulse via position 7; the control switch goes to position 8 and from there to position 12, the connection contact of the reverse magnet Rm 3. The control switch stops here.

While the control switch D overflows its positions 7 to 12, after picking up the second series of impulses, selector relay WR switched its switching arm wr to position 5, so that the forward magnet Vm 3 of the storage system Mc could meanwhile receive the third series of impulses. The cam disk of the storage system Mc was turned from the zero position forward by as many steps as the number of current impulses corresponded to the third series of current impulses. In position 12 of the control switch D, the reverse magnet Rm 3 now receives current surges when the pulse contact ii is closed until the cam disk of the system has returned to the zero position when it is rotated backwards. With each response, magnet Rm3 sends earth impulses to line L via its contact irm3.

The next series of rushes is after the selector relay WR its Shift arm wr has driven into position 6, again by the forward magnet Vm i recorded and from the reverse magnet Rm i via the control switch arm d I lifted out again in position 17. This game continues as long as Arrive series of current impulses in the line transmission.

After the end of the election, the pulse receiving circuit for the forward magnets is opened by contact 3 g of a relay G, not shown. If the line transfer is triggered, the occupancy relay C drops out. The selector relay WR is de-energized and remains at the step on which it was last. If the storage systems are still full, they are emptied. Has z. B. just received the forward magnet hm3 of the storage system Mc current surges, so after the relay V has dropped, the relay S is energized. Relay S interrupts the circuit of relay E in the line transmission Ue at contact s 5 and thus blocks this in a known manner against premature occupancy. Since relay S is still energized, control switch D moves from position 7 to position 12. Here the reverse magnet Rm 3 is actuated in pulses. During the last backward step of the cam disk of the storage system Mc, the cam disk comes to the zero position and opens the holding circuit for the winding I of the relay S at the contact i mc II held parallel to the magnet Rm 3 . Relay S has a slight dropout delay, and so after opening contact ii and closing contact i2 the control switch magnet D receives a current impulse via its position 12 and its switching arm d II, which drives the control switch to position 13, where it stops.

As indicated by dotted lines in Fig. Ia, the normally closed contact 4v of the relay V, which switches on the start relay S immediately after receiving the first series of impulses and thus gives the signal for the start of the transmission of the stored current impulses, can also be replaced by a contact x of the power transmission. This contact can, depending on z. B. from one set by the number current surges Follow-up drive, the symbol at the beginning of the transmission of the stored series of current impulses if necessary, only give after receiving several series of current impulses. In this case More storage systems than three to four per line transmission are also necessary. In the latter case it is also necessary to empty the storage systems when tripping ensure that the occupancy relay C of the line transmission Ue closes the circuit for the start relay S when it drops through contact 6 c.

Claims (7)

PATENT CLAIMS: i. Surge storage devices, in particular for telephone systems with multiple. Storage elements for storage one after the other, if necessary in cyclical repetition, made available while saving in the one and adjusted during the storage in the other direction of rotation and be controlled by a common impulse transmitter, characterized in that that a continuously working, the pulse ratio of the stored current surges determining switchover contact (i) of the common impulse transmitter via its rest side (i2) when initiating the storage, the connection of the storage element to be retrieved (M) causes and after connection of this memory element on its working side (i x) its switch-back magnet causing the transmission of the stored current surges (Rm) switches on in pulses. 2. surge storage device according to claim i, characterized in that that the changeover contact in. Depending on the beginning of a storage emptying in Activity is set. 3. surge storage device according to claim. r, characterized that the reverse magnets the stored current surges directly through their own contacts (rm i, rm2, rm3). q .. Impulse storage device according to Claim 2, characterized in that the relay (S) which characterizes the start of the delivery of the stored current impulse series is dependent on zero position contacts (i ma ... i mc, 2 ma ... 2 mc) of the storage elements (M) from Contacts of the forward magnets (towards i ... Vm3) and of a relay (V) bridging a series of impulses. 5. surge storage device according to claim q., Characterized in that that the start of the delivery of the stored series of current impulses is also dependent of a switching means (x), which only after receiving a certain selectable Number of the series of current impulses to be stored comes into effect. 6. Impulse storage according to claim q., characterized in that the start of the delivery of the stored Relay (S) characterizing the series of current impulses the switching circuit for the Control switch (D) assigned to the reverse magnet is prepared. 7. surge memory according to claim q., Characterized in that the beginning of the delivery of the stored current surge series characterizing relay (S) has a parallel to the reverse magnet through the working side (i I) of the pulse contact can be influenced winding (SII), which the advance of the Control switch (D) after emptying all storage systems from the control switch step occupied by the last set: reverse magnet to the following control switch step. Attached publications .: Austrian patent specification No. 159 263; German Patent Nos. 718935, 6o8 53I.