DE1561210B2 - CONTROL DEVICE ON A MEMORY CONTROLLED TYPE LEVER PRESSURE UNIT TO INCREASE THE WRITING SPEED - Google Patents

Description

The invention relates to a control device for increasing the writing speed of a memory-controlled Printing unit with overlapping hinged, d. i.e., type levers that overlap on their way, with a device for storing an identifier for the type lever attached and with a device for comparing this identifier with that of the subsequently triggered one Type lever to control the time sequence of the triggering of the type lever to be struck in succession depending on their spatial distance in the type lever segment.

DT-AS 11 81 241 shows a partial solution, but none very effective increase in typing speed for normal type lever machines, because there always uses a constant clock frequency

ίο becomes and only with double-character actuation a The clock frequency is changed.

Magnetic cores as information storage elements as in the subject of the application are not used. The magnetic storage cores must not be confused with the release magnets of the type levers will.

The magnetic storage cores represent an information store of any length of time, for the last triggered type lever.

Only the comparison of the type lever that was triggered last with the type lever to be triggered again gives the information, how long to wait before the magnet of the type lever to be triggered is energized and thus the release takes place, so that there is a significantly higher impact sequence. The by the subject of the registration In principle, the time constant that can be determined for each lever has been set in steps up to four levers on the right or left, as the theoretically further shortening of the stop sequence of

} o more than four lever distances due to the carriage advance movement is limited.

The task of the writing speed of type lever printing units by means of overlapping strokes to increase the type lever also concerns the older proposal according to DT-OS 14 86 879, in which it is provided that the triggering of type levers to be struck consecutively depending on their to control spatial distance (neighborhood position). DT-OS 14 86 879 contains the basic idea however, to increase the writing speed as when logging in, solves the problem on one completely another way, namely purely mechanically.

The solution after registration, on the other hand, uses electronic circuits in conjunction with magnetic

4s cores as storage elements and can therefore be used as a novelty solution, because the effort is much lower and the control takes place without mechanical intervention in the writing mechanism.

The object of the invention is not only to recognize the same type lever, but also adjacent ones To differentiate between type levers and in chronological order and thus to control their actuation.

The invention is characterized in that an electrical storage and comparison device Circuit with a number of the type levers according to their spatial position in the segment associated magnetic storage cores is provided, of which each type lever is controlled a group of several magnetic storage cores adjacent to the magnetic storage core via a decryption circuit in 2. B. negative magnetization is switchable that a pulse control circuit is provided to trigger a reading process when entering a new character at the same time as the magnetization the group of memory cores assigned to this character, and that the read pulses generated thereby a buffer and a reshaping logic to match the distance between the type group and

bels from the previously posted equivalent resistance combination turns on to a clock generator determining the work cycle of the machine, so that its cycle sequence corresponds to the distance of the named type lever is shortened.

The invention is further characterized in that the individual magnetic cores of the various Type lever assigned group of magnetic cores for all type levers the same spatial arrangement has and that the reading process by means of the ι ο magnetizing current when driving a type lever opposing current takes place through all magnetic cores, so that during the reading process only so many Magnetic cores for generating a pulse on the read lines assigned to these cores can be reset ι s are than the distance of the type lever of the newly entered character from the type lever of the previous one corresponds to the posted sign.

In the drawing shows

F i g. 1 shows a section of the magnetic core arrangement as assigned to the actuating elements. The memory cores 1 to 10 are shown for a character X with the set current Ix and for a character Y with the set current Iy . The reset current Ir flows through the wire 15 of the reset line. When resetting, read pulses are generated in read lines 11 to 14.

F i g. 2 shows a timing diagram of a time sequence. The set current 16 for a character X is shown with the reset current 18 and the sum of the currents 19 through a participating core (e.g. core 1). The setting of the cores generates negative pulses 21, which are not evaluated, the cores are set in positive magnetization (cf. 23 in Fig. 2). With the character Y that follows later with the setting current 17, further cores 8, 9 are set. The cores 1, 2 that are no longer energized receive only the reset current 20. This creates a positive read pulse 22 in the read lines 11 to 14, which is evaluated. With the reset current, the cores 1, 2 are reset to negative magnetization at 23 and generate the read pulse 22 in the process.

Fig. 3 is a block diagram. The decoding stages 25, 26 receive from the control of the writing unit 41 the code of a character is supplied via line 39, via a start pulse on line 38 the Pulse control stage 27 is started and the evaluation begins. Read pulses arise during the evaluation the reading lines 11 to 14, which are stored in a memory 28 and in a shaping stage 29 for Control of the adjustable resistors 34 to 37 are used. The controlled resistors 34 to 37 delay the triggering of the printing process for the offered character in the via a control line 40 Control 41 of the printing unit.

Application, general task

In a type lever typewriter, the types are arranged side by side in the type basket. If you press the key of a character and then want this character a second time for Bring stop, you have to wait until the cam lever again after stopping the first character is locked. Only then can it be triggered again. This waiting time can be shortened according to the invention if adjacent type levers are triggered because the cams cannot lock into place needs to wait. Rather, you can trigger the second, other type lever while the first is on the relapse path.

It must be noted that the angle of the trajectories on which there are move the type lever to the common stop point. The further away one type lever is from the other is, the closer the point moves to the attachment point at which the falling back and the striking one meet Touch the type lever and thus obstruct each other.

The times are distributed, for example, on an IBM C type lever typewriter as follows:

Double letters sequence 10.5 characters / sec.

1st combination sequence 11.5 characters / sec.

2nd combination sequence 15 characters / sec.

3rd combination sequence 16.7 characters / sec.

4th combination sequence 18.2 characters / sec.

5th combination sequence 19.3 characters / sec.

and following about 20 characters / sec.

A character that is posted two or more times in a row is defined as a double letter.

As a!. Combination is a sequence of characters named whose type levers are next to each other.

A sequence of characters is defined as a 2nd combination or more, the type lever of which is two or more Lever clearances are apart.

In purely numerical writing, the digits are generally four or 4 · η levers apart.

The probability that the same type lever will be triggered one after the other is not estimated greater than 20%.

Without changing the typewriter, this would mean an average writing performance of

= 16.7 characters per second

10.5 ■ 20 + 18.2- 80
KX)

possible if the stop sequence is controlled depending on the lever distances. For alphanumeric Writing, this value is even better on average.

Technical status, advantages, disadvantages

Solutions are known that separate the sequence of characters into double letters and not double letters permit: (DT-AS 11 81 241) Siemag.

The profit achieved on expenditure is low, around 10% for alphanumeric letters. For devices with It is conceivable for computers to use a program in the write process that stores the distances in coded form and the subsequent time is calculated for each new attack. This solution results in optimal utilization of the writing unit, but requires memory and a special program. Storage locations are expensive, and this solution is only possible for devices with appropriate computers.

In the following, the solution according to the invention will be described, which with extremely little technical Effort gives a good approximation of the optimal theoretical writing performance.

Principles

The attached type lever is stored in a magnetic core arrangement (Fig. 1), the magnetic cores are 1 to 10. A core 1 to X is available for each lever. Before a new type lever is triggered, an electronic comparison is made with the magnetic cores, which, depending on the distance between the levers, shortens the waiting time between the stops.

10 bi

The distinction was only made up to the 4th combination, for example. In principle it is without further possible to carry out the circuit up to the 5th, 6th or higher combination.

Storage, explanation based on the wiring principle

F i g. 1: The code assigned to type lever 4 is X. Memory core 4 belongs to type lever 4. Code A "is decrypted and in the form of a current Ix through core 4, as well as through core 1 to 3 on the left and through core 5 to on the right 7. These seven cores thus switch to negative magnetization, which is retained even after the current is switched off (rectangular ferrite storage cores known)

The code y belonging to the lever 6 and core 6 is now decrypted. The current Iy arises. This means that core 8 and 9 are switched to negative magnetization, while cores 3 to 7 have already been switched to negative.

While the current Iy flows and after the cores belonging to code y (= lever 6) have switched negatively, a reset current Ir of the same magnitude but in the opposite direction is switched on. The currents are neutralized in nuclei 3 to 9; these nuclei remain in negative magnetization. However, only the reset current flows through cores 1 and 2, which drives these cores into positive saturation magnetization. A positive pulse (or negative pulse, depending on the winding direction) is induced in reading lines 11 and 12. After the cores have switched over with certainty, the reset current is switched off. Only then is the current Iy switched off. These seven nuclei (3 to 9) remain in negative magnetization for the next comparison.

Reading impulses

Two cores were reset by the reset current Ir , which resulted in pulses induced on two read lines (11, 12). If a code Z had been deciphered instead of y and core 5 with cores 2 to 4 and 6 to 8 had been excited, only core 1 would have been reset and it would only be on one read line (11, 12, 13 or 14) an impulse emerged.

A lever distance means an impulse on one of the existing reading lines. Two or three lever distances mean impulses on two or three read lines. Four or more lever distances mean impulses on all four reading lines. The same lever means no resetting of a core and therefore no impulse on a reading line.

Pulse evaluation and clock device

The read pulses are stored in memory units belonging to a read line (e.g. flip-flop, 28, FIG. 3) stored. Via a reshaping stage 16, this information is reshaped in such a way that

one pulse on a line 30, two pulses on a line 31, three pulses on one line 32, four pulses on one line 33,

generate a current (Fig. 3).

An adjustable resistor 34 to 37 is connected to each of the lines 30 to 33 (or other Switching elements, e.g. B. Relay).

A clock in the device is set to double-letter speed, i. E. H. on slowest cycle time. By connecting the adjustable resistors 34 to 37 to 30 to 33, the cycle time in (f be shortened according to the graduation, so that the optimum impact speed is obtained.

Handling of special keys and special codes

The cycle time shortening described can only take place from codes or lever assignments that are included in the Core wiring Fig. 1 are included. All other codes or levers are like double letters treated, d. that is, they get the slow attack sequence. This means that type levers that are used very seldom need Codes are not included in the core arrangement, which is equivalent to a reduction in effort.

Lever and code assignment

A code is assigned to each lever. The order of the cores corresponds to the lever arrangement. The lever position is set by soldering the switch core wires to the corresponding decoding stages (Fig. 3) electronically reproduced.

If the core circuit is built on a pluggable board, then by exchanging the boards /, another lever arrangement or another code ^ can be ignored.

For this 2 sheets of drawing

Claims (3)

ι ο t> i patent claims: 1. Control device for increasing the writing speed of a memory-controlled printing unit with overlapping hinged type levers, with a device for storing a Identification (t ... 10, Fig. 3) for the type lever attached and with a device to compare this identifier with that of the subsequently triggered type lever for control depending on the time sequence of the triggering of the type lever to be struck in succession of their spatial distance in the type lever segment, characterized in that as Storage and comparison device an electrical circuit with a number of the type levers according to their spatial position in the segment associated magnetic memory cores (1 ... 10, Fig. 3) is provided, of which at Each type lever controls a group of several adjacent to its magnetic storage core Magnetic storage cores via a decryption circuit (25, 26) in z. B. negative magnetization it is switchable that a pulse control circuit (27) is provided for triggering a reading process each time a new character is entered, this is done simultaneously with the magnetization of this character assigned group of memory cores, and that the read pulses generated here via a Intermediate memory (28) and a reshaping logic (29) one of the distance between the type lever to be struck from the previously posted equivalent resistance combination (34 to 37) to one of the The clock generator (41) which determines the working cycle of the machine is switched on, so that its cycle sequence is shortened according to the distance between the type lever mentioned. 2. Control device according to claim 1, characterized in that the group of magnetic cores assigned to the individual magnetic cores (1 ... 10, Fig. 3) of the different type levers has the same spatial arrangement for all type levers and that the reading process is carried out by means of a magnetizing current ( Ix, Iy) when activating a type lever, the opposite current (Ir) through all magnetic cores occurs, so that during the reading process only as many magnetic cores can be reset to generate a pulse on the reading lines (11 to 14) assigned to these cores as the distance between the type lever of the The newly entered character from the type lever corresponds to the character previously posted. 3. Control device according to one of claims 1 and 2, characterized in that the magnetic memory cores are arranged on an electrical plug-in board.