DE1201100B - Printer with rotating type drum - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Im. Α .:

G 06k

German class: 43 a -41/03

Number: 1 201100

File number: G 22131IX c / 43 a

Filing date: March 12, 1957

Opening day: September 16, 1965

The invention relates to printers in the output part of a data processing machine, in particular an electronic calculating machine. At high speed of work such Machines, the mechanical printing process is comparatively often too slow, so that it does not work of the machine. The data to be printed out often accumulates faster than the mechanical printer can print them out.

It is known that by using printers with rotating type drum a relatively can achieve fast printing. The letter and number types are on the scope of the Drum mounted in axial rows. Each axial row contains the same type of letter or number. Markings are assigned to each row at one end of the drum and are used for this purpose to find out when a desired type is in print position. Are total if twenty-six letters and ten numbers are required, the drum has thirty-six Row types and associated markings. The printing paper comes together at the bottom of the drum passed with a ribbon. There is also a number of individually movable print hammers provided, which can be operated optionally and the paper against the ribbon and the type to press. These print hammers are usually in a row parallel to the type rows on the Drum arranged. Their number corresponds to the number of types in a series. The hammers are commonly operated by electronically controlled electromagnets. Such a printer can do this with every revolution of the drum print a full line. The paper moves one after each revolution of the drum Line on.

The speed and security of the printer's operation largely depends on the Way, the signals assigned to the characters to be printed control the print hammers. It is known, generating signals on the drum itself or on a separate drum rotating with it To affix marks that are used for comparison or identification.

According to the invention, a new approach is taken that in such drum printing units Shift registers are used. According to the invention, the arrangement is made so that one or several shift registers are provided to which the pressure signals are fed and at their output one input of a comparison device is connected, the second input of which is connected to reading heads one Printer with rotating type drum

Applicant:

General Electric Company, Schenectady, N.Y.

(V. St. A.)

Representative:

Dr.-Ing. W. Reichel, patent attorney,

Frankfurt / M. 1, Parkstrasse 13th

Named as inventor:

Jacob Goldberg, Bonnar Cox, Palo Alto, Calif.

(V. St. A.)

Claimed priority:

V. St. v. America dated August 27, 1956 (606 410)

known drum is connected, which provide code signals, which the type characters of the type drum correspond.

In order to achieve a particularly simple device, according to the invention, each register is in divided into several, preferably two, parts, for each of which a special comparison device is provided which compares the code signals with the circulating print signals in each register part and in the event of equality, an output signal is generated. This has the effect of an additional short memory achieved without actually needing such a memory.

It is also advantageous to make the arrangements so that a special Switching device is connected to which a sequence circuit is connected, which the output signals the comparison device in time with the circulation of the print signals in the registers of the series after forwards to the switching devices, their output signals to the type control devices to get redirected. These switching devices preferably consist of a separate group of flip-flop circuits belonging to each register part, which as a result of the counter to the gate circuits applied clock pulses successively the output pulses of the comparison devices received forwarded.

Usually such printers are also required to provide zero suppression; H. the places in front of the highest digit of a number are free

509 687/201

leave and not fill in with zeros. Should z. B. the number 382 reproduced in a six-digit machine the representation would be 000 382. The three zeros to the left of the number will be printed out, unless measures have been taken to prevent this process. There are different ones for this known possibilities.

In a further development of the invention, there is a particularly advantageous solution for zero suppression in such a way that a sensing head, which deviates from the code signal representing a zero Responds to code signals, to the gate circuits of the sequence circuit directly or via OR circuits supplies one of three coincidence pulses required to print a zero that are designed as flip-flops Switching devices in their second stable state until the end of the current drum rotation remain if a number other than zero is printed in a position to the left and that via the "one" output of this flip-flop all subsequent gate circuits via the OR circuits the necessary coincidence pulse is fed.

In the drawings, an embodiment according to the invention is shown.

Fig.! Fig. 3 is a view of a result printer;

F i g. 2 is a block diagram according to the invention;

Fig. 3 is a block diagram of a comparator;

F i g. Figure 4 is a block diagram of a shift register that can be used in accordance with the invention.

In FIG. 1 shows a printer with a type drum. The printer includes a drum 10 with Printing type rows 12, which are arranged in the axial direction on the circumference. At one end of the drum Identification marks can be arranged for the print type rows that contain the relevant font identify which is to be printed. In the present embodiment of the invention however, it is preferred to provide a smaller drum or disc 14 on drum shaft 16. This drum 14 is therefore rotated together with the drum 10 by the drive motor 18 offset. The code marks with which the comparison is carried out are magnetic or mechanically applied to this additional drum in the same key as it is in the data processing machine is used to which the result printer is to be connected. The reason for that is that in a known manner the drum is printed with a set of identification numbers for the rows Characters can be made while the data processing machine to which the drum is connected can have a different exit key.

A reading device 18 is used to scan the comparison marks on the drum 14. This reading device can comprise a plurality of reading heads which are aligned so that the output signals of the reading heads 18 consist of a set of signals occurring in parallel. These become one Coincidence device 20 supplied, which consists of an electronic circuit for comparing the from signals read by the reading heads 18 with the signals of the characters to be printed, consists. The latter signals are supplied by a pressure signal source 22. The pressure signal source may be the data processing machine that feeds these signals to a storage device that they Holds line by line so that the drum turns one revolution for each print line that you want to print will, can accomplish. Is there a coincidence between the type series at the pressure point and the signals supplied from the source 22, a control device 24 for the print hammers is actuated.

This control device 24 consists of a circuit for the selective excitation of thyratrons, the Feed electromagnets. These operate the hammers so that they hit the paper 26 that is passed between the hammer 25 and the drum 10. A ribbon 27 supplies the color for the required pressure. As usual, the hammers 25 are in a row below the lowest part placed on the drum and moved up so that it rests against the ribbon and the paper press the type.

The F i g. Figure 2 is a block diagram of an arrangement according to the invention. Signals from the pressure signal source are supplied to several registers 30, 30 'etc. one after the other, so that all registers contain the code for contain one line of the information to be printed. Each register includes, for example, eighty-four binary units. The first eighty-four binary units are entered into register 30. is If this register is filled, the next eighty-four binary units are introduced into register 30 ' etc. As many registers are used as are required to hold the data that should be printed in one line on the paper.

Methods for serial input from a single signal source are already known. A preferred one The method consists in placing an AND circuit in front of each register. The data from the signal source are fed to the individual AND circuits in parallel. The AND circuits are on the input side controlled by a counter. If the counter has counted so far that the first register is filled, so this register is disabled and the signals are fed to the second register. Has the counter counted so far that the second register is also filled, then the second register is blocked and the Signals are fed to the next register, and so on.

It is important here that multiple registers are used, each of which consists of two parts, labeled 30A, 305, 30'A, 30'B , and so on, respectively. When supplying data, each of these two-part registers can be viewed as a single register. When the data circulates, however, they only circulate in the "yi" part of the register, as if this were an independent register, while the data in the "B" part of the register also circulate separately. In this way, the contents of the registers for a type line can be scanned in a shorter time.

The drum 14 in FIG. 1 has two more tracks in addition to the one described. The one of these Traces supplies a pulse signal shortly before a series of letters or numbers of types under the print point got. The further track generates an output pulse every time the drum makes one revolution has executed. It is assumed that registers 30, 30 'etc. are filled. A pulse signal from the The first-mentioned track is fed to a flip-flop 32 and switches this over so that its output signal two AND circuits 34,36 is supplied.

A second input signal required for the AND circuit 36 consists of pulses from a clock pulse source. The clock pulse source supplies, in a manner known per se, the pulses through which all work the data processing machine can be determined in time.

The output signals of the AND circuit 36 are fed to a bit counter 37. As an example, let us assume that every character that will be printed

60 delivered if known per se on the drum Way not a zero, but a non-zero type is scanned.

The AND circuits 50, 4 to 50F are supplied with the output signal of the print position counter 38 as an input signal. The register 30 ^ 4 allows its contents to circulate, the print position counter counting up by one at the end of each circulation, and a signal appearing on output line A. The Kompara-

switches. If the flip-flop 52 ^ 4 is switched, so prepare there is an associated thyratron tube 56 ^ 4 before that in the event of ignition by a pulse, the ignition pulse

which the contents of the registers have been compared to the drum display to determine whether the different places of the type series a print

is represented by seven binary units. io tor 40 ^ 4 results in the finding that the contents of each register can hold twelve characters (eighty-four registers A and the drum display are the same, binary units), while each register has an output signal at the same time for all AND circuit part six characters (forty-two binary Units) from 50.4 to 5OF. Since, however, only the AND switch holds. The bit counter is a ring counter, which counts an input signal from the print point up to seven direction50 ^ 4 and then starts counting again. The counter 38 receives, only this is opened and gives a seven output signals are the shift pulse output signal, which the associated flip-flop 52,4 generator 39 is supplied to the register in operation
set so that their contents circulate. After filling the
Bit counter 37 is its output signal of the AND circuit 34 supplied as a second input signal, so 20 source 62 energizes a hammer, which is a sign that it emits an output pulse. The output prints. The ignition pulse source 62 is excited, after-pulse of the AND circuit 34 is fed to a print position counter 38, which can count up to six,
before returning to its initial count position.

The output lines of the counter 38 are to be followed by the 25 or not.
Letters A through F are designated and are identified with those in As mentioned, each register can be preceded by circulation

similarly labeled inputs of AND- a total of eighty-four binary unit circuits tied together. th record. Therefore, when the environment

The final output of the print position counter running each half of a forty-two binary 38 register is used to reset the flip-flop 32- 30 units to recirculate. With the present execution. The bit counter counts to seven before it returns to its embodiment form of the invention representing seven binary unit initial state. When it represents its seventh letter or number. At the end of the number it gives an output signal to that of the circulation of seven units therefore has the printing point counter, which hereby counts to one. AND circuit 50 Λ the associated flip-flop 52 A The print position counter counts to six before it is actuated or not. The register continues the cycle. It and offers the comparator the next seven units is therefore necessary for the bit counter to represent six times. The drum code is re-circulated by the so that the print position counter is compared by six numbers. At the end of the Verlen advances. If the shift pulse generator 39 supplies the registers 30, 30 'with switching pulses of the same period for the second set of seven binary switching pulses, then the 40 units run, the comparator 40 A converts an output content in the two halves of the register. The signal from, or not, depending on whether there is a match in the circulating contents, the comparison device exists or not. At this time, 40 B, 40 'A, 40' B is at flashed or comparators 40.4, matching the AND circuit 50 is opened and B, etc. fed, with the corresponding registers makes the flip-flop 52 B, which the associated Thyra- 3oA, 305, 30 'A, 30' B, etc. are connected. 45 tron tube 56 B ignites. For comparison purposes, all comparators circulating in register 30a are therefore compared with one

each set of seven binary units in the comparator, whereupon, if they match, a signal 50 is fed to the subsequent flip-flops 52 C to 52 F. It should be noted that all registers let their contents circulate simultaneously, that all comparators carry out the comparison simultaneously and that all groups of AND circuits and flip-flops are supplied with the associated comparator numbers. The output signals of Kompara- ren 55 are in communication, in turn veranlastoren40M and 40 'B are each six other not sen that an on-the printing point characters represented AND circuits supplied. From this it is printed or not printed,
to see that the output signals of the comparator If the type drum continues its rotation, so direct

Ren 40 B, 40 'A, 40' B corresponding circuits to the signals of the drum 14 are sequentially counted, as they are for the output signals of the 60 of the counter 37, 38 a. The register halves 30,4 , comparator 40A are described. 30 ' A, 30' B etc. all bring their content every time

With each AND circuit 50yl to 50F stand for circulation when signals from the drum 14 from flip-flops 52 Λ to 52 F in connection and are given that a letter or a number of these operated. An input signal of the AND approaching the print point. At the end of the cycle circuit 50.4 consists of the output signal of 65 of the contents of register 30 generates the ignition pulse first stage A of the printing point counter 38. A further source 62 is a pulse which those thyratrons res for the actuation of AND circuit 50.4 ignited, the input signal required to be ignited by their associated flip-flops is made ready by a sensing head. The flip-flops 52 Λ to 52 F

at the same time the code signal of the drum 14 is supplied. In this way, the contents of the register at Circulation compared with the code representation of the type series, which is located at the printing point.

The output signal of the Kamparators 40 A is fed to six AND circuits 50.4 to 50F at the same time. The output signal of the comparator 40 B is further six AND switch not shown

are only reset after one complete revolution of the drum has been completed. As the thyratrons be ignited in that a capacitor is discharged through it, which only once before the start of the If the drum is loaded in the printing cycle, the thyratrone can only be used once with each revolution of the printing drum be ignited.

The OR circuits 54 B to 54 F and the arrangement 60, which determines whether a zero or no zero appears on the drum, are used for the zero suppression. No zeros on the drum 14 as a characteristic the fact that there is at the printing position not zero, a trigger pulse of the AND circuit 50 ^ 4 is directly and to the AND circuits 5OB to 5OF via OR circuits 54 B is found to 54 F supplied. It should be noted that one condition necessary for this circuit to work is that all numbers from one to nine must pass under the print point before the zero row reaches it. It is therefore necessary to reset all flip-flops before the numerical printing part of the drum begins to pass through the printing point. This does not require any additional circuit, since the zero suppression is usually only required in those cases when only numbers and no letters are to be printed. If both letters and numbers are to be printed together, zero suppression is usually not desired.

If, under these conditions, a number is to be printed on a line, then one of the flip-flops 52 ^ 4 to 52 F is left in its switched state. It should be pointed out at this point that the output signal of the flip-flop 52 ^ 1 is fed to the OR circuits 54 B to 54 F in its switched state. The output of the flip-flop 525 is supplied to the OR circuits 54 C to 54 F. In the same way, the subsequent flip-flops (with the exception of the flip-flop 52F) provide output signals to the subsequent OR circuits. Accordingly, if the flip-flop 525 was left in its toggled state as an indication of the fact that one of the numbers from one to nine has been printed, the subsequent AND circuits SOC to 50F receive their third required input and are able to accept a Print zero if a zero is required in these places. However, the AND circuit 50 Λ does not receive a preparation input signal and cannot print a zero at this point. If the flip-flop 52 D and none of the previous flip-flops were toggled, then a zero could only be printed in the places that were switched over by the flip-flops 52F. and 52 F can be operated. If mark and penny values are to be printed, then no zero suppression connections are provided in the places to the right of the decimal point; if desired, the ones digit can also not be included in the zero suppression circuit.

The AND circuits and the OR circuits shown in FIG. 2 are shown are known per se.

3 shows, for example, the implementation of a comparator. The signals from the reading heads 18 are used to flip-flops 70 a to 70 g according to the seven-bit code of the printing point approaching type series, or not.

This operation is to the AND circuits 72 a to 72 g, which are connected so that they are a Record the output signal from the flip-flops when they are in their toggled state, prepare or not. The bit counter 37 gives successive output signals to the AND circuits 72 a to 72 g, which are connected to the inputs of the comparator via cathode amplifiers 74 a to 74 g are. If the bit counter rotates six times, the code signal corresponding to the print position is set in rotation six times.

The flip-flops 70 a to 70 g are reset after the series is printed. The comparator has two inputs, namely one of the cathode amplifiers 74 α to 74 g and the second from the circulating register with which the comparator is connected. For example, the input signal fed from the cathode amplifiers to an AND circuit 76 and an inverter 78. That The input signal from the circulating register is fed to a further AND circuit 80 and an inverter 82 supplied. The outputs of the AND circuits 76 and 80 become an OR circuit 83 forwarded. The output signals of the OR circuit 83 are fed to an AND circuit 84. The outputs of the AND circuit 84 are used to reset a flip-flop 86. At the beginning of each operating cycle of the comparator an AND circuit 88 is supplied with a clock pulse and a start pulse to one output line of the flip-flop 86 to a high potential. This is fed to an AND circuit 90, their output signal based on an interrogation pulse, the timing of which is described below is supplied to all AND circuits 50 Λ to 50F will.

In the comparator, at the beginning of a comparison cycle, the flip-flop 86 is set so that the an output line carries high potential. At the end of the comparison cycle, the AND circuit 90, if a match was found during the comparison process, an output signal when the interrogation pulse is applied, since the flip-flop 86 remains in its toggled state. If a match does not occur, the flip-flop 86 is reset, and the AND circuit 90 gives at the time of the supply of the interrogation pulse no output signal. When there is an input signal, the inverters 78 and 82 no output signal. Therefore, if on the two input lines to the comparator two identical input signals occur, the AND circuits 76 and 80 are not open, since only one of the two required input signals is available. If the input signals at the comparator are not the same, then either the AND circuit 76 or the AND circuit 80 is opened and gives an output pulse which resets the flip-flop 86.

The interrogation pulse can be taken from a special time-controlled interrogation pulse source; it occurs between the seventh number of the bit counter and its starting number, or it can be an interrogation pulse from the successive output pulses of the print counter over a delay line be derived. The delay must not be so great that it is included in the next comparison cycle. The start impulse can be a special one Source or can be taken from the

Pulse are obtained which advances the bit counter to its first counting state.

Figure 4 is a more detailed block diagram of the shift registers. Each shift register consists of two parts, the register half A and the register halfß. The register halves are interconnected so that they act like a single register to which the data is fed in series. After the register is filled, a circulation command is issued and the contents of the register half begin to circulate in it.

Each register consists of as many flip-flops as are required to store the binary digits. Hence, eighty-four flip-flops are provided if the full register is eighty-four Stores binary digits. Each half of the register has forty-two flip-flops accordingly. A Part of these flip-flops is shown in the register ^. These are flip-flops 100 and 102 on the Receipt of the register. An output of the flip-flop is connected to the reset input of the via a diode 104 second flip-flops 102 connected. The other output of the flip-flop 100 is via a diode 106 with connected to the setting input of the flip-flop 102. Becomes a switching pulse from the switching pulse generator supplied, the diodes conduct, or not, according to the switching state of the flip-flop 100. This conduction or non-conduction is transmitted to the control electrodes of the flip-flop 102, which thereafter assumes the same state as that which the flip-flop 100 had. Meanwhile, the flip-flop becomes 100 causes it to assume the state of the binary digit signal applied to its input electrode will. These signals fed to the flip-flop 100 can either be derived from new signals from an AND circuit 108 incoming data or from old data that is circulated by the AND circuit 110 to be brought. A feed command is required to open the AND circuit 108, the output signal of which is fed to the OR circuit 112. The output signals of the OR circuit are amplified in amplifier 114 and either for setting the first flip-flop in the Register used or, if no outputs are received from AND circuit 108, is set the inverter 116 returns the input flip-flop to represent a zero.

To transfer the binary digits obtained from the last flip-flop of register A , an AND circuit 118 is opened, and only when the other required input signal, the feed command, is present. In this case, it feeds its output signals to an OR circuit 120, the output signals of which are amplified by an amplifier 122 and fed to a register, either to switch its input stage or, in the absence of an input signal from the AND circuit 118, to switch its input stage by the effect the inverter 124 to put in the zero state. If the contents of the register halves A and B are to be brought into circulation, the AND circuit 118 does not receive any feed command signals. The AND circuit 110, like the AND circuit 126, receives a circulation command. These two AND circuits are then able to feed the data received from the ends of the halves of the register to the corresponding OR circuits 112 and 120, from where they are reintroduced into the corresponding halves of the register. If new data is introduced into the register, it replaces the one already present in the register, since the old data cannot circulate and is therefore deleted.

The shift pulse generator 39 supplies pulses either for introducing new data into the register or to circulate the data already there. To introduce new data into the register an AND circuit 130 receives an input pulse from the signal source for the feed command as well a second input signal consisting of pulses that allow the retrieval of data from the source from which schedule them to be received. These pulses are output from AND circuit 130 to an OR circuit 132 supplied, then amplified in an amplifier 134 and supplied to the shift pulse generator 39, which accordingly generates the pulses used to introduce the data into the register will. If the register is full, a circular command, the same as the previous one, prepares the AND circuits 110 and 126 is identical to the command supplied, the AND circuit 136 before the the bit counters 37 received pulses of the OR circuit 132 and from there the switching pulse generator 39 for circulation in the two halves of the register.

The circulation command and feed command signals can be taken from the programming circuit of the Data processing machine are derived in which the present device is used. Of the In the present case, the printing process takes place during one complete revolution of the drum the register filling takes place during the next drum revolution. Since the one drum revolution used to fill the registers and the next drum revolution used to circulate the registers the circulation command and the feed command from the single pulse track on the Drum 14 are derived, which feeds the single pulse per revolution to a two-step counter, the Output signal alternately causes the feed and the circulation.

Claims (5)

Patent claims: 1. Printer with rotating type drum, characterized in that one or a plurality of shift registers (30) are provided to which the pressure signals are fed, and at the output of which there is one input of a comparison device (40), the second input of which is connected to reading heads (18) of a drum (14) known per se, the code signals supplies which correspond to the type symbols of the type drum (10). 2. Printer according to claim 1, characterized in that each of the registers (30) is divided into several, preferably two parts (30,4, 30 B) , for each of which a special comparison device (40A, 402?) Is provided which compares the code signals with the circulating pressure signals in each register part (30, 4, 302?) and generates an output signal if they are equal. 3. Printer according to claims 1 and 2, characterized in that a special switching device is connected to each comparison device (40, 4, 402?) (52.4 to 52F) is connected to 509 687/201 which is a sequence circuit (38, 50,4 to 50F) which the output signals of the comparison device (40) in sequence with the circulation of the print signals in the registers (30) the switching devices (52,4 to 52F) forwards their output signals to the type actuating devices (56.4 to 56F). 4. Printer according to claim 1, characterized in that the switching device (52.4 to 52F) are a separate group of each register part (30 A to 30B) belonging to flip-flop circuits, which as a result of the counter (38) on the gate circuits (50.4 to 50F) applied clock pulses successively receive the output pulses of the comparison devices (40.4, 40 B) fed. 5. Printer according to one or more of the preceding claims, characterized in that a sensing head (60) which responds to code signals deviating from the code signal representing a zero, to the gate circuits (50., 4 or 50 B to 50 F) of the sequence circuit direct or via OR circuits (54 B to 54F) delivers one of three coincidence pulses required to print a zero, so that switching devices (52 A to 52F) designed as flip-flops remain in their second stable state until the end of the current drum rotation, if a number other than zero is printed in a place to the left of this, and that the necessary coincidence pulse is fed to all subsequent gate circuits (50) via the OR circuits (54) via the "one" output of this flip-flop. Considered publications: British Patent No. 737,657; "Review of Input and Output Equipment Used in Computing Systems," Joint AIEE-IRE-ACM Computer Conference, March 1953, published by the American Institute of Electrical Engineers, p. 95 to 97; "Proceedings of the Eastern Joint Computer Conference," December 1954, pp. 22-30. 1 sheet of drawings 509 687/201 9.65 © Bundesdruckerei Berlin