DE857821C - Impulse generator - Google Patents

Description

Impulse generator The invention is concerned with pulsing for control purposes in telecommunications systems, in particular telephone systems.

In the known automatic telephone systems, there is a pulse cycle the normal intermittent number switch circuit in the Closing and interruption of the DC circuit of a relay relay with the ratio of interruption to closure of 6o to 40. each cycle represents one Election digit represents the circuit interruption being the utilized part of the cycle is. The power shutdown is a time that cannot be avoided in order to achieve the Prepare to receive the next impulse. The stepping relay must also be so be sized so that it operates on both long and short subscriber lines it can become that, in the case of short lines, after it has been strongly magnetized, it quickly occurs drops, and that with long lines it is actuated quickly, even if it is only weakly is magnetized.

In this context, the timing of the pulse generator otherwise there is a risk of faulty connections.

The object of the invention is to increase the speed and reliability with which control pulses are transmitted from a transmitting to a receiving point. This is achieved according to the invention in that an alternating current applied by the connecting device to the subscriber line is rectified by a valve that rotates when the current impulse generator expires, so that, depending on the angular position of the electric valve, positive or negative pulses are applied to the line for the rapid delivery of pulses .

The pulses emitted are picked up by polarized relays. In this way, the positive and negative half-waves are used completely off. There is no loss of time during the voting process. The sequence of the dial is also not tied to specific speeds. The speed regulator of the well-known number switch is omitted.

A line gain for the establishment of a connection is achieved according to a further invention that the dial is operated both in one and the other direction and that for certain digits, for example i to 5, the dial and the electric valve in one direction and for certain other digits, e.g. B. o to 6, the dial and the electric valve can be rotated in the other direction. In this case, pulse combinations of one to a maximum of five pulses are sent out. The long expiry times of the current impulse generator and the setting times in the connection device are thus eliminated.

The invention is described in more detail below with the aid of the examples shown in FIGS. It shows: Fig. 1 the overview diagram of a connection device, Fig. 2 the circuit diagram of a subscriber set with a direct current loop, which is equipped with a rectifier number switch, Fig. 3 the circuit diagram of a subscriber set to which, as soon as the memory is switched on, alternating current is applied to the subscriber line FIG. 4 shows the circuit diagram of a memory for cooperation with the subscriber set circuit FIG. 2, FIG. 5 shows the circuit diagram for another arrangement of the pulse relays in the memory, FIG. 6 shows the circuit diagram of a memory for cooperation with the subscriber circuit FIG. 3, FIG. 7 the circuit diagram of a memory for co-operation with the subscriber circuit Fig. 2, but mechanical using memory and control selector, Fig. 8, the top view of the rectifier number switch dial and finger stop, Fig. 9 is a side view, partly along the line interface 9-9 8, FIG. 10 shows a section along the line 10-10 in FIG 9, FIG. Ii a section along the line ii-ii in FIG. 9, FIG. 12 a detail of the spring set in the rectifier number switch, FIG. 13 a top view of a number switch rotatable in two directions, FIG. 14 along a section the line 2-2 of FIG. 13, FIG. 15 the enlarged reproduction of a detail of FIG. 14, FIG. 16 a section along the line 4-4 of FIG. 14 FIG. 17 a plan view of the number switch from below with the cover plate removed 18 shows a plan view of the number switch with the number disc removed, FIG. 1 the circuit diagram of a subscriber set with the number switch of FIG. 13 and the following, FIG. 2o an overview of the position of the rectifier with different digits.

If we first turn to Fig. 2, the subscriber circuit shown there is of the rectifier number switch apart from the usual type. The rectifier number switch, which will be described later in connection with Figs. 8 to 12, contains a revolving rectifier R and a normally closed contact spring set S. The circuitry of the rectifier number switch is as follows: When the dial is brought out of its rest position, pin P 3 causes spring B to break its contact with spring C , which removes a short circuit from rectifier R and lets them make contact with spring A. short-circuits the voice coil and the microphone. The pin P i causes the spring F to break contact with spring G until shortly before the point in time when the first finger hole reaches the finger stop; in other words, the subscriber loop is opened briefly every time the dial is moved towards the finger stop. When the dial is released, the rectifier R makes a half turn for each finger hole that passes the finger stop, but before the last finger hole passes the finger stop P i, the contact between springs F and G opens again, causing a brief interruption of the subscriber loop which causes the memory to be switched over to include the next digit. As can be seen from the description of the rectifier number switch below, the rectifier is always brought back to a specific polarity. If an odd number is selected, the rectifier is given a half turn to bring it into the normal position, the contact between springs F and G being interrupted during the half turn.

From the above it can be seen that when the digit i is selected, the initial current short of the line through the rectifier 1? in normal position sends out the first pulse to reproduce the digit i, and that when you let go of the finger washer, the circuit for the circuit to take up the next digit is interrupted before the rectifier reverses the current.

The subscriber set circuit shown in Fig. 2 is intended for use in a system having memories of the type shown in Fig. 4 where a DC loop exists in the subscriber line until dialing begins. Another method is to apply AC power to the subscriber line as soon as the memory is turned on. In this case, the Teilnehmerschaltun is shown in Fig. 3. In this arrangement, the contact springs F and G shown in FIG. 2 have been omitted, since it is not necessary to interrupt the subscriber loop when the finger washer is moved out of the rest position.

The construction of a suitable rectifier number switch is shown in FIGS. 8 through 12 and will now be explained. If we first turn to FIGS. 9 and 10 in detail, the number switch consists of two main parts, an upper part i with the normally closed contact set HC and a lower part 2 in which the rotating rectifier S is accommodated.

The upper housing i carries a dial 3 which is provided with the usual finger holes and sits on an axle 4 which rotates in a socket 5 in the housing i when it is driven by a spiral spring 6 , one end of which is attached to the dial 3 is, while the other rests in a recess in the housing part i. A segment 7 is fastened to the axle 4 by the nut 8. A pawl 9 is seated movably on the segment 7 and strives' invade the teeth of a Sperradesio under the influence of a spring ioa.

The ratchet wheel io is assembled with a gear ii and rotates loosely on the lower extension of the axis 4. Both are held by the flat head ii a of a bearing pin 12 when the lower part 2, which contains the rectifier, is screwed on. The ratchet wheel has a number of teeth equal to the number of different positions of the dial 3. Every second tooth is relatively long when calculated radially. When the number switch 3 is in the rest position, one edge of the segment 7 rests against a rear stop 13 which is formed in the housing i. A raised surface 14 along the inner circumference of the housing i in the vicinity of the stop 13 lifts the pawl 9 in so that it only reaches the high teeth of the ratchet wheel io.

When the telephone operator turns the finger washer 3 , the segment 7 moves clockwise, and when it has covered an angular distance which corresponds approximately to the distance of a finger hole, the raised surface 14 no longer rests on the pawl 9 , and the latter rotates around its bearing point a little, so that it grips both the long and the short teeth of the ratchet wheel. Should the finger disc be rotated a distance equal to five finger holes, i. H. should z. B. the number 3 can be selected, since there is a distance corresponding to two finger holes between hole no. I and finger stop ig, the pawl 9 engages in a short tooth. When the finger washer is released, the spring 6 rotates the ratchet wheel counterclockwise.

When the segment 7 approaches the rest position, the pawl 9 runs onto the raised surface 14 and thus lets go of the short tooth, but grabs the next long tooth again just before the segment 7 comes to rest against the rear stop 13. The purpose of this arrangement is to ensure that the rectifier S always returns to a specific polarity position.

The rest spring set consists of five springs A, B, C, F and G (Fig. Io), which are inserted in a block of insulating material p , which sits on the upper housing i. Two pins P i and P 3 sit on segment 7 in such a way that when the finger washer is brought out of its rest position, pin P i opens the contact between springs F and G , while pin P 3 opens the contact between springs B and C opens and springs A and B make contact. The segment 7 consists of insulating material.

We now assume that the digit i is chosen. When the finger is inserted into hole no. I (Fig. 8) and the finger washer is brought out of the rest position, pin P i grips the end 15 of the extension of spring F (Fig. 10 and 12) and breaks the normally existing contact between the springs F and G. Spring F is cut out at the lower end and provided with an oblique shoulder16. If hole no. I has been moved by less than two finger hole distances, then pin P i runs over the projection 16 (FIG. 12) and releases the spring F , so that when the finger reaches the finger stop ig, contact between the again Feathers F and G is made. The three normally closed contact springs A, B and C are drawn in the rest position in FIG. When segment 7 is rotated out of the rest position, pin P 3 releases spring B, causing contact with spring C to be broken and contact to be made with spring A. Springs A, B and C remain in this position until the dial is back in its original position.

When the dial 3 is released, after it has covered about '' 'a finger hole division, pin P i again grips the protruding projection 16 of spring F and again opens the contact between springs F and G.

When segment 7 reaches its normal position at stop 13 again, contact between springs F and G is restored.

The lower part 2 houses the rectifier disks S (Fig. 9 and ii). They are pushed onto a socket 21 made of insulating material; By means of nuts 22, the removal brush 2oa is pressed on one side against the rectifier disk and the removal brush 2ob is pressed against the disk on the other side. A bearing pin 12 which passes through the bushing 21 is screwed to a gear 23 and rotates in bearing bushes 24 which are attached to the upper and lower walls of the rectifier housing S2. The bearing pin 12 is grooved so that the rectifier set S and the pick-up brushes 2oa and 2ob rotate with the bearing pin 12 and the gearwheel 23 when it is inserted through the bore of BUCIISC 21.

The upper and lower grinding brushes 2oa and 2ob run on grinding surfaces 24a and 24b which, as shown in FIG. Ii, are attached to the inside of the housing 2. The external connections are connected to the contact pieces 24a and 24b. The gears ii and 23 are interconnected by intermediate gears 25 which are attached to one another and held by a bearing pin 26 which is seated on the underside of the housing part 2. The ratchet wheel and the gears are assembled so that the revolving rectifier part S is in the position shown in Fig. Ii when the wheel io is in the position shown in Fig. Io. The transmission ratio of the various gears is such that the rectifier part S makes a full revolution when the finger washer 3 rotates through an angular amount corresponding to two finger hole distances.

The setting of the current collectors 2oa, 2ob (Fig. Ii) is such that the pin P i grips the extension 16 of the spring F and opens the contact between the springs F and G when the collectors remove the insulating sections 27 between the slip rings 24a, 24b touch and position 2 of the ratchet wheel moves back past normal position i. Thus, the contact between these springs is opened before the waste contractor 2oa make 2ob with the next contact pieces contact.

As it is based on precise speed control of the rectifier number switch does not arrive, it is sufficient to weigh down the customer 2oa, 2ob at the ends, so that they work both as speed control blades and as pantograph brushes.

The surge generator shown in FIGS. 13 to 20 shows another embodiment.

The finger disk i is rotated clockwise or counterclockwise, depending on whether the finger hole is to the right or left of a marker pointer 34.

A pin P (Fig. 14, 16, 18 and ig) closes the contacts C i of the spring set 40 when the number disk i is in the rest position. If the finger holes i or o are drawn after a short pause, pen P is moved to the right or left and shortly after it has left its rest position, for example after the dial i has been rotated by a distance equal to 1 '/ "4 holes, the line loop is interrupted at C i and remains interrupted until the dial returns to the rest position.

Just before the movement of the dial ends, i. H. during the last 1.4-finger hole width , depending on the right or left contact C 2 closes and thus puts the rectifier directly in series with the calling line. The length of time during which the C 2 remains closed in the course of the backward movement and the polarity of the first and the following transmitted pulses depends on which hole has been rotated.

When finger hole no. 5 or 6 is pulled, disk i moves 63 /, positions clockwise or counter-clockwise before the finger touches stop 35. There is no change in the line loop until the drawn hole reaches the other position of finger hole no. I or o, whereupon the line loop is broken at C i and closed at C 2 via the rectifier in the same way as described above.

The rectifier is connected to the dial i by a gear and makes one revolution every time the dial moves two holes further. It is drawn clockwise when digits i through 5 are dialed and counterclockwise when digits 6 through o are dialed. When the dial is released, the rectifier returns to its rest position in the opposite direction. The rest position of the rectifier with respect to the line loop is shown at A in FIG. 2o. The two poles of the rectifier end in pick-up brushes B + and B -, which brush away over conductive segments S i or S 2, which are connected to the a-wire or b-wire.

If finger hole no. I is pulled as far as it will go, the disk i will move a distance of 2 '/, holes. Since the gear ratio is 2: 1, thus making the rectifier thereby i ',' revolutions and reaches the position shown at B in Figure 2o.. The first turn of the rectifier has no effect because the contacts C i either short-circuit it or break the line loop. If the line loop through C 2 and the rectifier is closed during the last% revolution of the rectifier, the a-wire is connected to the positive and the b-wire to the negative pole of the rectifier, with a positive pulse being sent into the line and lasts as long as the finger is held on the finger stop.

When you let go of the dial, the rectifier rotates% revolutions in the opposite direction, but just before the consumers 27, 28 reverse the polarity of the cable connections, pin P opens the cable loop at C 2 and closes the circuit at C 1, 1/4 positions, before the dial reaches the starting position.

As noted above, the rectifier is shorted to C i. The initial and the subsequent closure of the line loop adjusts the memory to the reception of the impulses.

When the digits 3 and 5 are drawn, the rectifier moves again to the position shown at B in FIG. The first pulse sent during the clockwise rotation of the dial becomes positive. If the dial is then released after selecting 3 , this is followed by a negative pulse and another positive pulse, whereupon the line loop is interrupted by the pin P on the contacts C 2. If the number 5 is selected, the first pulse during the clockwise movement is again positive, followed by a negative, a positive, a negative and another positive pulse, whereby the line loop at C 2 is interrupted.

If the dial No. o, 8 or 6 is pulled in the counter- clockwise direction, the rectifier assumes the position shown at D in FIG. 2o. In the case of the number 0, the output pulse is negative during the counter-clockwise rotation of the finger disc, which continues until the number disc and with it the rectifier pass clockwise to the normal position and pin P at C 2 breaks the line loop.

If the dial is released after selecting the number 8 , the original negative pulse is followed by a positive and another negative pulse during the return movement, before C 2 interrupts. If the number 6 is drawn, the original negative pulse during the return movement is followed by a positive, a negative, a positive and another negative pulse before the circuit is interrupted at C 2.

Initial positive pulses result when holes no. 7 and 9 are drawn and the rectifier goes into the position indicated at C in FIG. 2o. If digit 7 is selected, the original positive impulse is followed by a negative, a positive and another negative impulse. If the number 9 is drawn, the original positive pulse is followed by a negative pulse.

Similarly, when holes 4 and 2 are drawn, the initial pulse is negative and the rectifier assumes the position indicated at E in FIG. 2o. If the number 4 is drawn, the negative pulse is followed by a positive, a negative and a positive pulse. If number 2 is drawn, the original negative pulse is followed by a positive pulse.

The relationship between the pulses generated by the respective selected digit is given in the table below: Selected digit Generated pulses 1 + 2 - + 3 + - + 4 + - + 5 - + - + 6 + - + - 7 - + - 8 + - 9 + - 0 The mechanical structure of the device will now be explained in more detail (Fig. I # to 18).

The disc number i is seated at the upper end of a vertical shaft 2, retained by the screw 3. The guide plate 4 is held within an opening located in the middle annular recess i a number of the disk and covers the screw. 3 The axis 2 can rotate freely in a bearing 5 which is pressed into the housing 6 of the device or otherwise fastened.

A bush 7 can rotate freely on the bearing 5 and has a lever 8 pressed onto its lower end, to which one end of a spring 9 is riveted. A second lever io is attached to the disk i and has a through hole through which the bushing 7 freely passes. A finger love ii is attached to the upper end of the bushing 7 between the disc i and the lever io.

Lever 8 carries the insulating pin P, by means of which the contacts 40, which influence the line loop, are actuated.

The device is assembled by first pushing levers 8, 10 and ii onto socket 7 and then placing the latter on socket 5. The dial i and axle 2 are attached and the upward end of the lever io is attached to i by screws 39 .

The pin P passes through the slot 12 in the upper part of the housing 6 (see FIG. 18) and normally closes the contact between three springs in the chamber formed by the housing 6 at C i (FIG. 16). Axis 2 passes through an eye 6a in the upper part of the housing 6 and is held in place by a nut 13 .

A finger 14 is fastened to axis 2 below the nut 13 with a wedge. Two disks 15 U and 15 L on axis 2 form a chamber in which a clock spring 41 is located. The outer end of the spring 41 is attached to the circumference of the disc 15 U and the inner end to the vicinity of the disc 15 L. Before the discs 15 are pushed on, they are rotated so that the spring 41 is tensioned until the protruding lugs 16 U of the disk 15 U and 16 L of 15 L come to lie on both sides of a stop 17, d-2r protrudes from the housing 6. This prevents the spring from unwinding.

A finger 14 a is attached below the lower disk 15 L.

The fingers 14, 14 a grasp on opposite sides corresponding approaches 18 and 18 a, which protrude from the upper and lower disks 15 U and 15 L. All fingers 14 and washers 15 are fixed on axis 2 within the housing 6 by the nut ig.

Between the nut ig and a second nut 2o, the axle 2 carries a gear wheel 21 which meshes with a pinion 22. The latter sits on an axle 22 a, which carries a wheel 23 , which in turn drives a gear 24. The ends of the axis 22 a sit in a shoulder 25 which is attached to the housing 6 and in the upper part of a rectifier housing 31 which forms the lower part of the housing 6 .

In the rectifier element 26 , the upper connection is connected to the collector 27 and the lower connection to the collector 28. The rectifier is fastened to the insulating bushing 29 on the axis 3o. The gear 24 is, passes to the upper end of the spindle 3o reasonable i introduced its lower end to the socket 29 of the rectifier housing 31 through the floor. The socket 29 can rotate freely in the upper part and lower part of the housing P. The pickups 27, 28 are curved springs that are diametrically opposed i and normally do not touch anything, but when they rotate with the rectifier, make contact with semicircular conductive segments S i and S z attached to the side wall of the housing 31 and are connected to the tip or ring of the line. When the user's finger hits the finger stop 35 , the rectifier pick-up springs 27 and 28 are in contact with the same segments S i and S 2 with which they were in connection when contact C 2 was closed. Therefore, when the pulse generator moves forward, only one pulse is sent, regardless of which digit is dialed.

On the circumference of the dial there are ten finger holes at equal intervals with a stop 34 which is attached to the housing 6 and protrudes between the holes 5, 6 and with a further stop 35 which is attached to the housing 6 and emerges between holes o and i. Between the holes o and i is a ratio 1 excessively wide space. As indicated at 33 , the digits are attached to the top of the housing 6 and are visible through the holes in disk i. Of course, the numbers can be replaced by letters or other identifiers that signify the desired process, or combined with them. The finger holes i to 5 turn the dial clockwise from 34 to the finger stop 35.

The gear consisting of the wheels: 21, 22, 23, 24 is dimensioned so that each time the disc i: rotates a distance corresponding to two finger holes, the rectifier 26 with its pick-up 27 and 28 performs a full revolution. The dial i is moved clockwise by a distance that is equal to 21, / / 4 finger positions if no. I is pulled to the stop 35 , or equal to 4 "/, positions if hole no 6 # "/ 4 positions if hole # 3 is drawn, 8. '/ 4 if hole # 4 is drawn, and 103 / / 4 positions if hole # 5 is drawn. The disc moves counter-clockwise by the same distances as just mentioned when the number o, 9, 8, 7 or 6 is drawn.

If one of the finger holes i to 5 is pulled up to the stop 35 , the tip of the finger inserted into the finger hole grasps the right edge of the lever ii at a distance equal to two finger holes from the stop 35. If the number is i, then it does so after the finger washer i has moved a bit equal to -3 #, finger holes. The lever ii is normally in the position shown in FIGS. 13, 14 and 15. A continuation 36 of a spring 9 down normally rests in a recess of the housing 6 and a normally upward protrusion piece 37 thereof is located in a distance-from the top 38 of the lever io. The lever io and its extension 38 move forward with the dial. When the fingertip grasps lever ii and rotates clockwise, the socket 7 and the lever 8 and spring 9 attached to it rotate with it. This pushes the extension 36 of the spring 9 out of its recess in the housing. The appendix 37 of FIG. 9 is raised as appendix 38 has been moved out of its way. The fingertip moves disk i and lever ii further until the finger stop 35 is reached, whereupon disk i is released and, under the tension of a spring 41, runs back in the counterclockwise direction. When the disc has moved a distance corresponding to 3, "'4 of a finger hole, the extension 38 of the lever io grips the end 37 and transmits through it, as well as lever 8 and bushing 7, the driving force of the spring to the lever ii, which thus during the rest of the counter-pointer movement of the disk i is returned to the rest position. The contacts C 2 therefore open # / 4 positions after the start of the return movements and C i closes 11 "4 positions later.

During the return movement of the disk i, d, 2r GI "iclir, - r in G-2 counter-clockwise direction. The polarity of the impulses that are sent out while C 2 is closed depends on which hole has been drawn.

In the rest position ii, 36 falls into the recess of the housing and 37 comes out of engagement with 38. If the dial i is pulled in the opposite direction, the lever ii, which extends equally far on both sides of the stop 35 , is rotated counter-clockwise and returns to the rest position when the extension 38 hits the other end of the extension 37.

When finger holes 5 or 6 are drawn, finger lever ii is only reached when finger hole 5 comes to the point where finger hole i hit finger lever ii. Therefore, regardless of which digit is selected, the lever ii moves two finger holes either clockwise or counter-clockwise and actuates the contacts C i and C 2 in the manner described above.

Spring 41 tries to press the shoulders 16 of the disks 15 U and 15 L against the stop 17. This keeps the dial in its normal position. When the disk i is rotated clockwise, the finger 14 a grasps the attachment 18 a attached to the lower disk 15 L. Extension 16 L can move freely away from stop 17 , but extension 16 U is held and thus the spring is tensioned. When the dial is released, the disk i and the rectifier return to the normal position under the tension of the spring 41 until the shoulder 16 L hits the stop 17 again. Similarly, when the disk i is pulled in the opposite direction, finger 14 grips the lug 18 of the upper disk 15 U. The spring 41 is again tensioned, and when the disk is released, the disk i returns to the rest position and stops, when the approach 16 U hits the stop 17.

How the dialing system works in its application in a system, where until the beginning of dialing a DC loop in the subscriber line will now be described with reference to Figs.

If we first turn to Fig. I, then if a calling party Participant picks up the receiver, a circuit is closed for via the fork contact the subscriber relay in the subscriber circuit of the office, an R-connection set starter and voter selects a free R-connection set, one related to it Memory finder switches on a free memory and a B-connection set finder chooses a free B-phrase, the one with a first group voter and a second Call finder is in communication.

The calling line is connected through the second call finder and a free first call searcher having access to the calling line.

The memory shown in Fig. 4 shows only that part of the circuit which relates to the rectifier selection. When the calling line is switched on, the relays RAR, RBR and RCR pick up, and relay HR is energized in a circuit of the battery via the external normally closed contact of relay R i R, the normally open contact of relay RBR, resistor R 3 and the upper one Winding relay HR to earth. Relay RBR holds and releases relay RAR. Relay HR stays in series with the calling line via both windings and forms a circuit for the off-delay relay R i R via its lowest working contact. Relay R i R applies a battery to both windings of the differential relay DR, so relay speaks DR not on as long as its two wicks are energized via the normally closed contacts of relays PR + and PR - , relay R i R takes the battery voltage from resistor R 3 w2g. Official sign is applied via the transmitter TT. The circuit remains in this state until the subscriber begins to dial.

When the number disk of the equalizer number switch is brought out to the rest position, the pin P 3 opens the contacts B and C, removes a short circuit from the built-in equalizer and the subscriber loop is temporarily interrupted. Relay HR fills off, from - r not the delayed relay R i R. When the subscriber loop is closed again, this time via the rectifier R in the partial bucket apparatus, current flows from such a direction that it triggers the polarized relay PR + (Fig - 4) excited. This current flows from the 40o Hz 50 V Stroinquelle via a protective lamp GL, the normally closed contacts of the relays HR and RAR, the a-wire, the rectifier number switch in the subscriber station, b-wire and the normally closed contacts of the relays RAR and HR, relay PR + interrupts its normally closed contact, thus opening one winding of relay DR and causing it to pick up. Relay DR energizes relay R 3 R, which forms a circuit for relay R 4 R. Relay DR forms a holding circuit for relay R i R via a normally closed contact of relay HR. When relay HR closes its normally closed contact, relay DTR picks up, holds itself and removes the official signal from the subscriber line.

The first impulse is always a positive impulse. The next pulse is a negative pulse that immediately follows the first pulse, causing the polarized relay PR - to open its normally closed contact and relay PR + to close its rube contact. This switching takes place so quickly that the very slightly drop-off delayed differential relay DR does not drop out. Relay DR thus remains out of equilibrium and attracted until the impulse generation 2 has ended. The second or negative impulse activates the polarized relay PR -, which releases the short circuit of relay CH 2. Relay CR 2 is maintained via its own normally open contact, resistor R 4 and a normally open contact from relay R 4 R. The following third and positive pulse causes the counter relay C R 3 to respond, etc.

When the pulse series is over, the subscriber loop is again briefly interrupted by pin P i in the number switch, just before the number disc comes to rest, as has already been explained in the preceding description of the number switch structure. The relays PR + and PR - remain on their normally closed contacts, so the differential windings of relay DR are both closed again, relay DR drops out and lets R 3 R drop out. Relay R3R switches off relay R4R, but before the delayed relay R 4 R interrupts its work contacts, a circuit is temporarily closed, from the battery to the outer left break contacts of relay R 3 R, work contact of relay R 4 R, resistor R 3 and the top winding of relay HR to ground. Relay HR is again excited and remains on the subscriber line, the loop of which is now closed because the dial is in the rest position.

Another circuit is also temporarily closed from earth via the left break contact of relay R 3 R and the work contact of relay R4R to the counting relay CR. For example, suppose that counting relays CR 2 and CR 3 have been energized. The aforementioned circuit is closed via the normally open contact of relays CR 2 and CR 3, normally closed contact from relay CR 4, normally closed contact from relay TR i, resistor R 5 and the winding of relay XR 3 to the battery. If relay R 4 R interrupts its working contact, a short circuit is removed from relay TR i, which is now in series with relay XR 3 in a circuit from earth via the working contact of RCR, the winding of relay TR i, working contact from XR 3 and the winding of relay XR 3 to the battery.

depending on which relays CR 2 ... CR io are actuated, the relays XR i ... XR 4 excite individually or in various combinations and apply selection potentials PN i ... PN io to the C bank of the via their contacts the withdrawal of the leading tax voter PO.

Relay XR 3 applies, for example, potential PN 3 via its normally open contact and the normally closed contacts of relays XR i and XR 2 to step no. I in the C-bank of the selector PO controlling the withdrawal. The C-arm is connected in a manner not shown to the grid of the tube V i by a pair of test tubes VI, V 2. The grid of the tube V 2 is connected to the b-vein, which is switched through to the first group, vätiler (see Fig. I) via the spoicher finder, the R-phrase, B-phrase finder and the B-phrase. Relay TR i grounds the a-wire, which is switched to the first group selector via the B-arm of selector PO in its first position. When the a-wire is grounded, the first group selector looks for a free connecting line connected to the potential PN 3 , and when such a line is found, a gas-containing valve tube belonging to the tubes V i and V 2 ignites and causes, that the voter is stopped.

Further relays XR or combinations of them are kept in the energized state Status when other digits are dialed and control the establishment of the connection. The four relays XR and relays TR i, five together, are sufficient for Sp, fuse one under ten digits. In a dialing area with seven-digit numbers would be seven such groups of these five relays exist. These groups of five Relays have the same task as memory selectors. You are in favor of the method of rectifier choice, which is banned here overnight, not much, but they work a lot faster as voters and for this reason are used in memory as he is in this one Modification is described.

If relay R4R interrupts its normally open contact, the counting relays CR2 ... CR io held up to that point drop out, the memory selector circuit returns to the rest position and waits for the next digit to be dialed, which causes the memory to appear again, as described above Carry out dialing processes, which in this case means tightening and holding the corresponding relay combination of the second group.

It is not essential to use pulse relays polarized in memory. As shown in Fig. 5 , the polarized relays PR + and PR - can be replaced by ordinary relays R i and R 2, each in series with oppositely connected rectifiers S - and S + , but in this case a smaller one results Dialing speed.

As already explained, instead of the method described in connection with FIGS. 2 and 4, where the subscriber line forms a direct current loop until dialing begins, another option can be used where alternating current is applied to the subscriber line as soon as the memory is switched on . The subscriber set circuit for this work method is shown in Fig. 3. In this case, no contact springs F and G are required in the rectifier number switch, since it is not necessary to open the line loop when the number disc is moved out of its rest position.

The memory circuit associated with use with this approach is shown in FIG. 6 ; it is similar to that of Fig. 4 except that its operation differs in the following respects.

If after the response of the relay RBR and RCR relay RAR closes its normally closed contact, alternating current is applied to the b-wire of a calling line via the protective lamp GL and since the rectifier R in the subscriber set (Fig. 3) is short-circuited, the a- AC current back. The polarized relay PR + does not interrupt its normally closed contact because of the rapidly successive positive and negative half-waves. Relay PR - however, breaks its normally closed contact due to the presence of a rectifier S - which is in series with the polarized relay PR- in the pulse circuit and suppresses the positive half-waves with respect to relay PR-. Relay RBR, which closed its normally open contact at the same time as relay RAR closed its normally closed contact, applies a battery to both windings of the differential switched relay DR. Relay DR energizes relay R 3 R, which in turn energizes relay R 4 R. The circuit remains in this state until dialing begins.

If the dial of the number switch is pulled away from the rest position, the short circuit is removed only by the rectifier R, current flows through the loop in the positive direction and energizes the polarized relay PR +. Relay PR + interrupts its normally closed contact, but relay DR remains picked up via the normally closed contact of relay PR - , which is pushed into the rest position. Relay CR i picks up, holds, applies relay CR 2 to the normally closed contact of the polarized relay PR - and also short-circuits the rectifier S - so that an impulse can then take place without the disadvantage of an unnecessary impedance in the subscriber loop. The counting relays CR, the code relay XR and the relays TR operate as already described in connection with the memory circuit shown in FIG.

The switchover from dialing digit to WäbIziffer takes place when the * dial returns to its idle position and, as a result of the short circuit of the rectifier in the dial, allows alternating current to pass through the a-wire. Since relay CR i has short-circuited the rectifier S - , the two polarized relays PR - and PR + close their normally closed contacts, so that the differential relay DR drops out and relay R 3 R switches off, which as in the case of the memory circuit shown in FIG first the appropriate combination of relay XR in series with relay TR i can be attracted and held and then the counting relay CR is free for the selection of the next digit. The relays XR apply a selection potential PN i ... PN io to the C-bank of the selector PO controlling the withdrawal, the first group selector responding and determining a free connection in a line group being sought.

FIG. 7 shows how a memory circuit with memory selectors and control selectors can be converted to rectifier selection using a subscriber set according to FIG.

When the memory has reached the calling line, relay RAR drops out and relay RBR picks up, whereupon the subscriber hears the exchange signal, whose primary circuit closes via a normally open contact of relay RBR, the normally closed contact of relay DTR, the primary winding of the exchange signal transmitter TT and the trunk signal contactor DTI to the battery. Relay HR i picks up in a circuit from earth via normally closed contact from relay R i R, normally open contact from RBR and a winding from relay HR i to the battery. Relay HR i places its second winding between earth and a wire and relay HR 2 between the battery and the ring wire. The relays HR i and HR 2 pull in series with the calling line and the subscriber circuit whose rectifier R (Fig. 2) is short-circuited. Relay HR i lets the drop-off delay relay R i: R respond, which applies battery voltage to the two windings of a differential relay DR and earth to the armature of the oppositely polarized relays PR + and PR - . Relay DR does not pick up at this point in time because its windings are connected differentially. The magnet of the first memory selector D i is excited in a circuit from earth via the normally open contacts of relay RiR, normally closed contact of relay PR +, A -Arm, step i in the storage-controlling selector PI, step o, C-arm of selector D. i, winding of magnet D i to the battery. Magnet D i attracts its armature, but this selector only switches the rotating arms further when the magnet is de-energized again. The circuit remains in this state until the subscriber chooses the first digit. As shown at C , the memory selectors are provided with an extra bank of contacts, while the storage control selector Pr has a further bank, which is shown at A i .

If the participant begins to select the first dialed digit, the line loop is en momentarily interrupted as it is written Working in conjunction with FIG. 2. This causes the relays HR i and HR 2 to drop out. Relay HR i applies alternating current to the a-wire and applies the two polarized relays PR + and PR - in parallel to the b-wire. Relay HR i closes the circuit of relay DTR, which picks up and is held via a normally open contact of relay R i R. The exchange signal is therefore switched off for the rest of the connection from the calling line. Relay R i R has a drop-out delay and controls the triggering of the store. It does not drop out during the short time when the line loop is broken when the dial is pulled against the finger stop. After the line has been temporarily opened, the circuit is closed again, this time via the rectifier, as described in connection with FIG. The first pulse is always a positive pulse, so relay PR + picks up. It switches off magnet D i, which now allows the first memory selector to move from step o to step i. In position i, magnet D i is again excited, this time via the normally closed contact of relay PR - and the rotary arm A i of selector PI. The interruption of the normally closed contact of relay PR + removes the equilibrium of the differential relay DR, which picks up and allows relay R 3 R to respond. Relay R 3 R closes a response circuit for the magnet of the injection control selector PI, but the arms of this selector are not switched. Relay R 3 R keeps relay R i R energized and via another normally open contact it energizes relay R4R in a circuit - from earth via normally open contact from R i R, normally closed contact from relay HR 2, normally open contact from relay R 3 R and the winding of relay R. 4R to the battery. Relay R 4 R is maintained via its normally open contact and a normally closed contact from relay HR 2.

The first time the current is reversed in the subscriber line, relay PR pulls -.in and lets selector D i advance from step i to step 2. The relay PR + closes its normally closed contact and again energizes the magnet of the selector D i. This continues until the corresponding number of pulses has arrived. During the current reversal, which allows relay PR - and PR - to respond alternately, DR i does not interrupt its normally open contact, at least not so long that relay R 3 R can drop out, since the polarity reversals take place almost instantly.

At the end of the series of pulses, the line loop is interrupted again, whereupon both relays PR + and PR - remain on their normally closed contacts and cause the differential relay DR to drop out, causing relay R 3 R to drop out. Relay R 3 R opens the circuit of the magnet of selector PI, which advances from step i to step 2. Relay R 3 R also energizes via a normally closed contact relay HR i in a circuit from earth via the normally open contact of relay R i R, normally closed contact from relay HR 2, normally closed contact relay R 3 R, normally open contact relay R 4 R and a wickhing from RAais HR i to the battery. Relay HR i picks up, separates the alternating current from the a-wire and instead puts its second winding between earth and a-wire, via a further changeover contact it switches off the relays PR + and PR - and instead places relay HR 2 in between Battery and b-core. If the dial comes to rest and the line loop closes while the rectifier is short-circuited, relay HR 2 picks up in series with the calling subscriber line and the second winding of relay HR i. Relay HR 2 interrupts the holding circuit of relay R 4 R and the circuit of the first winding of relay HR i. The relays HR i and HR 2 remain energized in series until the dial is pulled for the next selection, whereupon the second memory selector iri moves forward in the same way as the memory selector D i. It can be seen that during the 25 to 50 ms, when the subscriber loop is interrupted at the end of each election, the following switching operations take place in the specified order: Relay DR drops, relay R 3 R drops, relay HR i picks up. All of this can take place with ease in the minimum allowable time of 25 ms. The line loop must remain closed for 15 ms so that relay HR 2 can interrupt its normally closed contact and relay R 4 R can switch off.

The circuit can be triggered by the caller at any time until the end of the dialing by breaking the line loop. Relay HR drops out, which in turn switches R i R jb, which both RCR and R 3 R drop and thereby interrupts all holding circuits. In normal operation, the memory is automatically triggered after the selection has been completed.

Claims (2)

PATENT CLAIMS-. i. Impulse transmitter for telecommunication systems, especially telephone systems, characterized in that is used for delivery of control pulses an applied by the interconnecting means to the subscriber line alternating current by a changing in waste course of the impulse transmitter polarity electric valve (R i, Fig. 2) in the same direction such that depending on the operational status of the pulse generator, positive or negative pulses are transmitted to switching means (PR +, PR -) arranged in the connecting device. 2. Impulse generator according to claim i, characterized in that the electric valve is rotatably connected via a gear (25, Fig. 9) to the shaft of the dial (3) in such a way that depending on the setting angle of the disc when this expires, the electrical valve is reversed several times. 3. Impulse generator according to claim i and 2, characterized in that the digits of the dial are assigned certain constant positions of the electric valve in which it is permeable in a certain direction. 4. Impulse generator according to claim i and 2, characterized in that the rotating electrical valve is coupled to the number disk shaft when the dial is returned, and that a current reversing device (2o a, 2o b, 24 a, 24 b, Fig. 9 and ii) is provided. 5. Impulse generator according to claim i to 4, characterized in that the electric valve in the rest position is only permeable in the same direction. 6. Impulse generator according to claim i and 4, characterized in that the current reversing device consists of two diametrically arranged contact arms (2o a, 2o b) on the electric valve, which grind on two semicircular contact segments (24 a, 25 b). 7. Impulse generator according to claim i, characterized in that a number of contact springs (A to G) are provided, which are actuated by pins (P i and P 3) of an insulated disc (7) rotating with the number disc in such a way that one pin (P 3) cancels the short circuit of the electric valve and the other pin (P i) briefly interrupts the line loop before the dial comes to rest. 8. Impulse generator according to claim i, characterized in that the dial is operated both in one direction and in the other direction, and that for certain digits, for example i to 5, the dial and the electric valve rotated in one direction and for certain other digits, b, -for example o to 6, the dial and the electric valve are rotated in the other direction. G. Current impulse generator according to claims i and 8, characterized in that the electrical valve is reversed several times in accordance with the numerical operations both in one and in the other direction of movement of the dial and that when the dial moves out of the working position, the first pulse is negative for the even digits , for the odd digits is positive. ok Current impulse generator according to claims 1, 8 and 9, characterized in that receiving means respond when the dial is actuated into a working position in the connecting device and that the receiving means respond in a pulsating manner when the dial moves back from the selected working position into the rest position. ii. Current impulse generator according to claim 10, characterized in that positive or negative pulses are emitted when the dial is rotated into different working positions. 12. Impulse generator according to claim 8 to ii, characterized in that contacts are provided which are closed during the last part of the rotation into the working position and during the first part of the selection of the return movement caused by the spring. 13. Impulse generator according to claim 8 to 12, characterized in that normally closed contacts which short-circuit the electric valve are opened during the rotation of the dial up to the vicinity of the initial movement and the end of the return movement. 14. Impulse generator according to claim i, characterized in that the positive and negative pulses emitted during the return movement of the dial act on relays (R i, R 2, Fig. 5, PR +, PR -, Fig. 4) in the connecting device, their contacts for control purposes such as B. Voters, memory can be used. 15. Impulse generator with connecting device according to claim i and 14, characterized in that the positive and negative pulses coming from the impulse generator on telephone relays (R i, R 2) which are bescbaltet with electrical valves or (wired with electrical valves) polarized relays (PR +, PR -) , some of which are activated by positive impulses, others by riegative impulses. 16. Impulse generator with connecting device according to claim i to 14 and 15, characterized in that the counting chain of a memory can be actuated by actuating the contacts of the polarized relays (R i, R 2, PR +, PR -, relays CR). 17. Current impulse transmitter with connection device according to claim 1, 14 to 15, characterized in that a differential switched relay (DR) is made to respond and hold for the duration of a pulse series emitted by the current impulse transmitter of positive and negative pulses, which after the drop is made by switching means ( R i, R 2) Converter relays (XR i ... XR 4) actuated, their contacts in one or combined switching positions potential (PN i ... PN io) according to the recorded number to the contact bank of the control selector (PO) making the withdrawal invest. 18. Impulse generator with connecting device according to claim 17, characterized in that several groups of converter relays are provided for a selection process, the switching of which takes place after each recorded and converted series of pulses by assigned relays (TR). ig. Current impulse transmitter with connection device i according to claim 14, characterized in that the contacts of the polarized relays (PR +, PR -) control the switching magnets of memory selectors (D i) in such a way that after setting the first control selector, the second to receive the current impulse transmitter Pulse series is provided. 20. Stronistoßgeber with connecting device according to claim 14 and ig, characterized in that for reversing from a Sp3ichetwähler 1 to the following a selector (P i) is provided, the circuit for the drive magnet after the relay (R 3 R) is interrupted and is only closed again when the next series of impulses is picked up by this relay. 1