DE1146295B - Circuit arrangement for setting electromagnetically adjustable switching means or character carriers - Google Patents

Description

Circuit arrangement for setting electromagnetically adjustable Switching means or sign carriers The invention relates to a circuit arrangement for setting electromagnetically adjustable switching means or symbol carriers by means of electrical pulse trains that are stored on rotating magnetic storage media, such as magnetic drums or infinite magnetic tape.

Such arrangements are used, for example, in semi-electronic telephone exchanges for setting dialers or charge printers and in calculating machines for setting the printing units. The inertia of the magnetic devices to be set presents particular difficulties in relation to the speeds of the input and output of pulses on magnetic drums or magnetic tapes. In known arrangements of this type, the problem is solved in that special transmission controls are provided between the magnetic recording media and the devices to be adjusted, which cause a time delay of the individual pulses. The ratio between the speed at which incoming impulses are stored and the speed at which they are extracted for setting the magnetic devices is about 6: 1.

For example, an arrangement has become known in telegraph technology at which a speed translation of the telegraphic characters is achieved by, that first the telegraph characters each on a track of a magnetic drum be saved. This drum rotates at such a speed that at the end of a character consisting of several steps, one drum revolution has taken place. Several characters are thus shown in parallel on the drum saved. These characters stored in parallel are then stored one after the other from a magnetic head moved from track to track by a special switching pulse tapped and transferred to: a second high-speed drum storage system in such a way that that .all characters now appear in series on one track. Of this The last drum memory is then sent out with a significantly higher one Telegraph speed. The arrangement is made so that with her too a reduction of the telegraph characters arriving at a higher speed can be done at a relatively low speed.

All of these known facilities require sub-translation or translation the speed special deceleration devices, which in case of small speed differences for example, designed as runtime chains or, in the case of larger differences, as a memory are. This makes them relatively expensive and involves the risk: that caused by the interposition of these devices a pulse distortion which can result in incorrect adjustment of the magnetic devices can..

These disadvantages of the known arrangements are made in accordance with the invention avoided in that clock tracks are provided on the magnetic memory, their Number corresponds to the number of possible steps of the mechanical switching means and on each of them at corresponding intervals for each sector of the magnetic memory One control pulse each for the pulse sequence recorded on the information magnetic track tapped magnetic head from track to track offset by one pulse length is. The clock tracks are sequential only during one revolution of the magnetic memory effectively scanned, and at the coincidence of a pulse of the clock tracks and a pulse of the pulse train recorded on the information magnetic track the mechanical switching means is switched one step at a time. According to Another embodiment of the invention are the clock tracks of a switching stage assigned to an incremental chain. It is useful for each sector of the magnetic memory a mechanical switching means is provided separately. However, according to further Formation of the invention also several sectors with a single mechanical switching means. can be assigned if, for example, several pulse trains are added together shall be. The invention is described below with reference to one in the 1 and 2 explained in more detail: FIG. 1 shows a circuit arrangement according to the invention in principle and: FIG. 2 a pulse diagram. for an arrangement according to FIG. 1.

On the magnetic drum M shown in FIG. 1, several magnetic tracks are shown, which can consist of one or more tracks. In the magnetic track B 1 consisting of a track, the pulses necessary for setting the printing unit are recorded in a known manner, which is not shown in detail. The number of records to be recorded. Pulse sequences depend on the number of type wheels or type bars in the printing unit. A sector of the magnetic track B 1 is provided for each pulse train. The magnetic track B 2 consists of several magnetic tracks, the number of which varies. according to the number of sectors of the magnetic track B 1. The magnetic track B 2 controls the connection of the individual type bars or type wheels of the printing unit to the assigned sectors of the magnetic track B 1. The magnetic track B 3 contains as many magnetic tracks as the individual type bars can perform steps. In the case of a decade number printing unit, the magnetic track B 3 would thus consist of ten magnetic tracks lying next to one another. Each individual magnetic track of the magnetic tracks B 1, B 2 and B 3 is a. Magnetic head M 1 to M 5 assigned. Since, as will be shown in the following, the magnetic heads M2 to M5 of the magnetic tracks B 2 and B 3 only come into effect one after the other, it is conceivable that only a single magnetic head can be used for each magnetic track. In this case, however, a mechanical displacement of the individual magnetic head from one magnetic track to the adjacent would be necessary. The mechanical displacement in turn causes a certain inertia, which would partially cancel out the advantage of the invention. It therefore appears expedient to provide a separate magnetic head for each magnetic track.

From the pulse trains recorded on the magnetic drum M by the to be controlled printing unit is shown in. Fig. 1 only a type bar 3, the on its side facing the roller 5, the type characters 4, z. B. Numbers or letters, wearing. The type rod 3 is in a known manner via the gear 2 and the pawl 1 moved step by step by one magnet R.

The mode of operation of the circuit arrangement shown in FIG. 1 is described in more detail with reference to the pulse diagram shown in FIG. 2 for the stored number 3152. It is assumed that the capacity of the printing unit is just sufficient for a four-digit number. In this case, the magnetic track B 1 of the magnetic drum M is divided into four sectors. These four sectors correspond to the four columns shown in FIG. After the count 3152 has been stored, three pulses are recorded in the first sector of the magnetic track B 1, one pulse in the second sector, five pulses in the third sector and two pulses in the fourth sector. Corresponding to these four sectors, the magnetic track B 2 of the magnetic drum M contains four adjacent magnetic tracks and the four magnetic heads assigned to them, of which only two are shown in FIG. Each of these four magnetic coils has a controlling effect in a known manner only in that area which corresponds to the assigned sector of the magnetic track B 1. These control pulses of the magnetic track B 2 are shown in FIG. 2 by the lines B 21, B 22, B 23 and B 24 .

It is now further assumed that the printing unit is a decadic number printing unit; each type bar 3 has ten number types. Accordingly, the magnetic track B 3 consists of ten, arranged side by side. Magnetic tracks on which pulses are recorded, the number of which corresponds to the number of sectors of the magnetic track B 1: The distance between these pulses of a magnetic track corresponds to the respective sector length. In addition, the pulses of one magnetic track are shifted by one pulse width, including the pulse pause, compared to the present magnetic track. Of the ten magnetic tracks of the magnetic track B 3, only five (B 31 to B 35) are drawn in the Dagraanm of FIG. 2, corresponding to the highest priority of the selected number. 3152.

While the magnetic recording on the magnetic track B 1 for every setting of the pressure works changes, the magnetic recordings remain of the railways. B 2 and B 3 unchanged.

With the revolution of the magnetic memory M is at the beginning of the first Sector in which three pulses are stored on the magnetic tape B 1; the magnetic head M2 excites the magnetic track B21. This increases the ignition potential of tube R 1 (Fig. 1) raised so far that in your. Moment; in which the magnetic head M 1 is the first Impulse of the red sector of the magnetic train, B 1 passed over, ignite the tube R 1 can, if at the same time the magnetic head M4 of the magnetic track B3 over the common Coincidence circuit K acts on the tube R 1: Since in the time in which the Magnetic head M 1 sweeps over the other stored pulses of the first sector, no further pulses are scanned by the magnetic head M 4, the in the magnetic head M 1 further induced pulses on the tube R 1 ineffective. Dramit becomes during the scanning of the magnetic head M1 over the first sector of the magnetic path B 1, the tube R 1 is ignited only on the first impulse of this sector and the circuit for the # magnet R of the printing unit closed. This attracts and switches in known way the type bar 3 by one step upwards: When you turn it further the magnetic drum M during this first revolution is at the end of the first sector the magnetic head M 2 ineffective and instead the magnetic head M3 of the adjacent magnetic track B22 effective. This increases the potential at the ignition electrode of the first tube R 1 switched off and fed to the ignition electrode of the second tube R 2. There now on the one hand on the magnetic track B 1 in the second. Sector the first pulse is recorded and on the other hand, on the first magnetic track B31, the Magnetbiahn B 31 a value clock pulse is stored is induced by the two. Pulses in the magnetic heads; M 1 and M 4 pass the ignition potential of the tube R 2 via the coincidence circuit K raised so that it ignites. This is in the pre-drilled, not closer illustrated manner, a second magnet R excited, which in turn, the associated, type bar not shown advances by one step. Approximately further on the second sector of the magnetic track B 1 stored pulses can over the magnetic head M 1 do not come into effect, d a also in the previously described Way, the magnetic head M4 does not transmit any further stored pulses.

The same process as for the first and second sectors of the Magnetic track B 1 has been described, is also repeated for the third and fourth Sector of this railway. Here, too, only the first in each case on lane B 1 are saved Pulse to ignite the tubes, not shown in Fig. 1, each of the third and fourth, also not shown, type bar of the printing unit assigned are effective.

At the end of the first revolution of the magnetic drum, there are those of the magnetic track B 2 associated four magnetic heads corresponding to the magnetized sectors of the magnetic tracks B21, B22, B23 and B24 (Fig. 2) came into effect one after the other. The magnetic head M4 of the first track B31 (Fg.2) of the third magnetic track B 3 of the drum M was here effective four times. All four type bars 3 of the printing unit are at the end of the first Rotation of the magnetic drum M set to the first step.

At the beginning of the second revolution of the magnetic drum M is with the help of the indexing chain F, the magnetic head M4 of the magnetic track B3 is switched off and the magnetic head M 5 switched on. This magnetic head M 5 is now in accordance with the second Magnetic track B 32 (Fig. 2) efegt stored pulses. As from the above Operation of the circuit arrangement shown in. Fig. 1 emerges, is in the .erste sector only the second pulse recorded on the magnetic track B 2 is effective. The type bar 3 of the printing unit assigned to the tube R 1 is placed on the second Step forward. When passing over the second sector of the magnetic track B 1 by the magnetic head M 1, the tube R 2 is not ignited because, as from the top Line of Fig. 2 shows that no further pulse is stored in this sector. In the third and fourth sectors of the magnetic track B1, the third is in an analogous manner and fourth type bar of the printing unit also moved one step forward.

From this mode of operation it can be seen without further ado that the switching a type rod 3 or the ignition of the associated tube R only then take place can. if: simultaneously with the excitation of the magnetic head M 1 of the magnetic track B 1 each of the heads of the two magnetic tracks B 2 and B 3 are also excited. Only when three magnetic heads are excited can one of the tubes R ignite.

At the end of the second revolution of the magnetic drum M are thus the first type bar 3 of the printing unit on the second step, the second type bar on the first step and the third and fourth type bar on the second, respectively Step. After one more rotation of the magnetic drums. take the first and third guy bar the third step. At the end of the fourth revolution of the magnetic drum M of the four type bars 3, only the third one is moved forward by one step. That The same also applies to the fifth revolution of the magnetic drum M.

This printing point control described is also shown in Fig. 2 and summarized for each type bar. This diagram shows at which times and at which rotation of the magnetic drum M pulses are given to the magnets of the respective type bars, which are designated in the diagram with T 1, T2, T 3 and T 4 .

Claims (5)

PATENT CLAIMS: 1. Circuit arrangement for setting magnetically adjustable switching means by means of electrical pulse trains which are stored in series on rotating magnetic memories in several sectors and which are stored under control by special magnetic tracks, characterized in that on the magnetic memory (M) clock tracks (B. 31, B 32 ... ) are provided, the number of which corresponds to the number of possible steps of the mechanical switching means (3) and. on each of which, at corresponding intervals for each sector (I to IV) of the magnetic memory (M), a control signal for the magnetic head (M1) picking up the pulse train recorded on the information magnetic track (B1) is stored offset from track to track by one pulse length that the clock tracks (B 31, B 32 ... ) are effectively scanned one after the other only during one revolution of the magnetic memory (M), and that when a pulse of the clock tracks (B 31, B 32 ... ) and a pulse coincide the pulse sequence recorded on the information magnetic track (B 1) the mechanical switching means (3) is advanced by one step at a time. 2. Circuit arrangement according to claim 1, characterized in that the clock tracks (B 31, B32 ... ) are each assigned to a switching stage of an indexing chain (F). 3. Circuit arrangement according to claims 1 and 2, characterized in that each of the sectors (I to IV). mechanical switching means (3) is assigned. 4. Circuit arrangement according to claims 1 to 3, characterized in that a single mechanical switching means (3) assigned to several sectors (I to IV) is. 5. Circuit arrangement according to claims 1 to 4, characterized in that all in the sectors (I to IV) of the magnetic information track (B 1) stored pulse trains are assigned a single magnetic pick-up head (M1). Documents considered: German Patent No. 522151; German Auslegeschriften Nos. 1021188, 1031827; U.S. Patent Nos. 2,872,665, 2,907,009, 2923922.