DE2439123A1 - CONTROLLED PRINTING DEVICE FOR ALPHA-NUMERICAL DATA - Google Patents

Description

CONTROLLED PRINTING DEVICE FOR ALPHA-NUMERICAL DATA

The invention relates to printing apparatus, and more particularly relates to printing apparatus for printing variable alphanumeric data on specific if necessary storable positions that are aligned with respect to other fixed data.

When printing business forms and the like, it is desirable to use the simultaneous Printing a form text or a form sample or one for direct mailing certain advertising printed matter and the like together with the printing of variable data, for example an address, on the individual piece of form and at maximum printing speed to be able to make, with which the respective printing press can be operated.

The invention is therefore based on the object of a printing device or a printing system to create, with which variable data can be stored in and with respect to others Have fixed data of the aligned position printed out.

The invention relates to a printing apparatus for printing variable data on pre-stored data and identified positions aligned with respect to other fixed data on an advanced path by a device for generating command signals and coded

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Data corresponding to the variable data of a selected multi-line format, a control device controllable by the command signals and acted upon by the coded data, the Character clock signals are generated in accordance with the sequential position of the variable data in the multi-line format, and by means for printing out the variable Data depending on the character clock signals by projecting one independently controllable flow of printer ink droplets onto the advancing web.

Advantageous further developments of this inventive concept are characterized in the subclaims.

The invention is explained in more detail below with reference to the drawings in an exemplary embodiment. Show it:

1 shows the block diagram of the individual structural units of a printing system

Features according to the invention;

2 shows a schematic perspective illustration of the printer unit of the printing system;

3 shows a schematic perspective illustration to clarify the arrangement

and assignment of the printing units and cylinders of a printing press that can be used in the printing system according to the invention;

4 shows the matrix or printing form division for the individual to be printed

Sign;

5 A and 5 B the block diagram of the coupling electronics of a control device for the Format header;

Fig. 6 shows the block diagram of the coupling electronics of head control units for

Adaptation to the usual address circuits of computers;

Fig. 7 is a circuit diagram of a connection unit for the main head controller

the system;

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8 shows the block diagram of the coupling electronics for the head controls 2, 3,

4 and 5 of the system;

9 shows the block diagram of the head controls for the end of the printing

Information;

10 shows the block diagram of the common coupling electronics for the nozzle

steering;

11A and 11B, respectively, show the gate circuit arrangement which is provided for the computer connection unit is;

j FIG. 12 shows the operational assignment and linkage between the units

according to Figures 5A, 5B and 6-10;

13 shows the side view of a plate cylinder to illustrate the format

depth and the decoder or the decoding, which is used in the time control the system pressure nozzles are provided;

14 is a diagram showing various control signals in the computer

connection unit as a function of a specific printing speed;

15 shows the combination of a block diagram and a schematic representation

to clarify the relationships between electrical signals for Actuation of an ink nozzle and the ratio of the flow of ink droplets with respect to the nozzle elements and the advanced web;

FIGS. 16A to 16G show a schematic representation to clarify the working principle of FIG Nozzle control electronics;

17 shows the schematic representation of an existing in several units

Ink supply and vacuum arrangement for a printing unit with five nozzles,

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which is part of an ink supply system, and

Fig. 18 is a schematic representation of an ink supply regulator which is part of the

Ink supply system is.

According to the block diagram arrangement shown in FIG. 1, variable and example data to be printed out on business forms in alignment with certain fixed dates in a Magnetic tape unit 30 stored on two magnetic tapes, the unit 0 and unit 1 are designated. The variable data are brought into a readable format and under Control of a computer 31 read into this. The computer 31 arranges the variable data for transmission to a computer connection unit 33 in an alpha-numeric character format around. The computer 31 can read the data stored on the magnetic tapes and takes care of the basic data control and the provision of the program sequence functions for the definition of the variable data at the input of the computer connection unit 33. The computer 31 also assigns the necessary input / output system and data lines Establishing a connection between the computer connection unit 33 and a cathode ray tube (CRT = C_athode Jtoy Tube) for operational monitoring and display 32.

The CRT operation monitor and display 32 has at least one CRT display unit visible information display and an assigned control panel or keypad on, above that the operator can enter into dialogue with the computer in order to obtain the necessary data and Enter information, such as various system parameters required for the operational process are. The CRT display also provides the operator with information generated by the computer relating to the operation of the system.

The unit 34 for the form position and the web speed has the necessary Converters, such as optical encoders, to provide the data that relate to the desired Format depth, the web speed and the speed of the main pressure cylinder. The web speed and speed of the main printing cylinder provide the necessary Zeitsteuerep. Or clock pulse inputs for the computer connection unit 33, so that this

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the necessary clock and control signals for coordinating the computer 31 and the nozzle control electronics 35 to control the printing ink spray nozzles for printing the variable Can provide information in the form of alpha-numeric characters that can be used in certain Assignment and alignment to be printed on the moving web.

The computer connection unit 33 has the necessary circuitry for receiving the converter signals from the unit 34 for the form position and web speed of the data control and timing information from the computer 31 and the status signals from the Nozzle control electronics 35 and the nozzles 36 to enable synchronization and operational control of the entire system. The computer connection unit 33 has in essential five basic building blocks on / the respective specific control and synchronization signals for internal use in the connection unit itself and for the operation of the nozzle control electronics, hereinafter referred to as nozzle controls. How related with the formation and projection of the ink droplets in certain positions on the moving web, the speed of which can optionally be changed, later It becomes clear that it is necessary to measure the time of the ink droplet release as a function of the web speed to control or regulate. The computer connection unit 33 has a circuit unit to control and monitor the form head to release the color droplets as a function of the belt speed and the form head on the main plate cylinder to be able to control precisely. The output signal of this connection unit, a corrected one Form head impulse (CTOF impulse) represents a basic control signal in the connection unit and serves as a reference from which to base all of the character marking and clock signals in the line unit for the subsequent control of the nozzles in the printing unit or in the printing units generated or derived. The CTOF signal is also dependent on set a desired format depth, which is selectable by the operator, whereby regarding the changing information to be printed by the color nozzles the changing format depths can be displayed or saved on the master cylinder can.

The computer terminal unit 33 has a main head controller for each printing unit. This main head controller receives the head clearance information from the computer and generates the

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required timing or clock signals for controlling the release of ink droplets through the first nozzle of this printing unit, to which the respective main head control is assigned. These timing signals are generated by counting clock pulses, the pulse sequence of which is directly proportional to the web speed. The operation of the main head controller is controlled by the CTOF pulse. The timing signals contain character marking pulses (STR1 - pulses) to provide a reference frame or a reference limit within which five spaced apart further character marking pulses (STR2 pulses) are formed, the STR2 pulses being the spring Defines the cycle for the release of a respective column of a 5x7 matrix or matrix, within which all alphanumeric characters of the entire system are generated. The main head controller also generates additional timing signals that ensure control or monitoring functions for head controllers 2, 3, 4 and 5 of the associated printing unit. The main head controller also generates a print request signal for the nozzle controller, which would be released before the time of the actual droplets he η, so that the nozzle No. 1 of the printing unit can be prepared for the printing process.

The computer connection unit 33 also has a common head control circuit for the Receipt of an address signal and control functions for operating the main head and the head control 2, 3, 4 and 5 of a printing unit. These control functions include the INACTIVE, EFFECTIVE, STOP BALANCING and START BALANCING signals as well as a start signal from the computer that controls the operation of the main head firing of each printing unit and synchronizes the operation of the remaining four head controllers for each printing unit.

The computer connection unit 33 also contains identical circuit units for the second, third, fourth and fifth head control of each printing unit for generating time. Control signals for the respective droplet release at each of the assigned nozzles 2, 3, 4 and 5 of this printing unit. These timing signals also include character marking pulses (STRl -impulse) and further character-marking-impulses (STR 2-impulses), which are the same Fulfill function, such as those designated accordingly and through the main head control generated pulses. The STRl and STR2 pulses from the respective head controls 2, 3, 4 and 5, however, are generated to control the displacement of the nozzle along the direction of movement.

/ 7 5 0-9 8 1 0/0 7 A 1

to count the path within a printing unit. This shift is fixed during a particular printing operation, but may be within the mechanical limits of the predetermined Düsenau ^f construction itself and change the desired printing format. In other words: the distance between the nozzles in the direction of web movement can be changed, as can the respective distance between the nozzles along the transverse direction to the movement of the web. Each of the head controls 2, 3, 4 and 5 has a circuit for the clock-correct control of the generation of the STR1 and STR2 pulses in order to count or compensate for the distance between the nozzles in the direction of web movement. Each of the head controllers also includes circuitry for generating a print request signal which is applied to the associated nozzle in order to prepare the nozzle in question for printing.

The head control circuit, which is identical for all head units, is located in the computer connection unit 33 to count the number of characters printed by each nozzle so that the end the message to be printed indicating control signal can be generated so as to STRI and STR2 pulses for the main head control and head controls 2, 3, 4 and 5 set each printing unit, as well as to indicate to the computer that the printing of a certain set of variable data has ended. This circuit unit also generates Memory marker signals for controlling the output of the encoded alpha-numeric character data to the nozzle control electronics.

The nozzles of each print unit are a set of memory and print buffer memories assigned to the respective memory marking signals from the common main head controller respond to the character data from the computer collective output line to mark an output with seven lines that correspond to a specific character in a Seven-bit representation of an ASCII code. Each of the nozzle controls has one Addressing, a scanning or query line and a data control circuit for monitoring of receiving the information from the computer as well as the facilities to make the connection to each of the nozzles so that the computer can monitor their respective printing status can determine.

The print format in the embodiment of the invention described here has a length of thirty-eight characters on each print line. In addition, a ten-line shift is

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per inch (about 4 characters per cm) of the web movement. The line spacing between the print nozzles of a specific print unit and between the print units themselves is variable and only through the mechanical structure of the press, the mounting of the mechanical Part of the printing units, etc. limited.

The nozzle controls 35 are both coded with the alpha-numeric output data as well as being acted upon by the STR1 and STR 2 pulses from the computer connection unit 33, wherein the printing of the alphanumeric characters by each of the nozzles within a Pressure unit is controllable. A matrix generator for each of the nozzles generates a sequence of Pulses that synchronize with respect to the generation of the ink droplets in the nozzles themselves are. This pulse train is generated by the character-marking pulses from the computer terminal unit clocked so that each column of the 5 χ 7 matrix to release the color droplets in a certain assignment and alignment to the moving web, regardless of whose speed is time-correlated.

The pulse train output from each matrix generator is provided by a digital-to-analog converter circuit device, with a separate circuit responsive to each of the matrix generators, thereby generating a low level video sawtooth or staircase signal which can be set to seven different voltage levels for each column of the matrix. These low level video signals are amplified and serve as control voltages for a charging tunnel through which each of the successive Droplets in the stream of droplets ejected through each nozzle according to the desired shift is loaded in the direction transverse to the path movement. The video amplifier is synchronized according to the excitation of a piezoelectric crystal, which forms the droplets in each of the nozzles so that the loading of the droplets is precisely matched to the generation of the droplets.

The nozzle controls 35 also have a high voltage deflection circuit to the Pallets of a deflection tunnel impose a static charge through which each of the charged droplet passes through it, causing each droplet by a distance or a Distance is deflected, which is directly proportional to the length of each droplet during the passage

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walk through the loading tunnel! impressed charge. Uncharged droplets are not deflected and are caught by a collector before they hit the web, so that they are irrelevant for the printing of the alphanumeric characters.

The nozzle controls 35 also include well known trim and droplet sensing circuits to detect and correct the matching or equalization of the color droplets, if such a correction is required.

Finally, the system has a unit for monitoring and controlling the paint supply and of the flow of paint to each of the respective nozzles. This part is in Fig. 1 with reference number 37 marked. Each of the printing units has an ink feed in multiple designs on, whereby each of the five nozzles of a printing unit operates simultaneously and in parallel with Color is supplied from paint containers. The uncharged droplets of paint that flow through each of the respective collectors assigned to each of the nozzles are intercepted by a multiple vacuum return connected to each of the headers. the Ink unit 37 further comprises suitable filters and pressure regulators to ensure the correct ink supply to ensure each of the spray nozzles.

Fig. 2 shows a typical embodiment of a printing unit 38 in operational assignment to a movable path 39. Each of the five paint ejectors 38a, 38b, 38c, 38d, and 38e of the printing unit 38 is used to print a corresponding print line 40a, 40b, 40c, 40d and 4Oe. As shown in FIG. 2, the print lines 40a-40e are separate from one another equally spaced, but the distance between the lines can be adjusted by a suitable setting of the holder for a desired or all of the paint nozzles 38a-38e in one Direction transverse to the movement of the web 39 can be changed. With the system described here each of the nozzles 38a-38e is at a distance D from the adjacent nozzle in the printing unit 38 arranged. The distance D for the device described here is 6.35 cm (2 1/2 inches). These dimensions for the allocation of the respective nozzles in the Pressure unit is only to be understood as an example, and it should be emphasized that the distance D between each nozzle, if desired, by a suitable modification of the circuit of FIG Connection unit can be changed, as can also be seen from the following description

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will show the construction and operation of this unit.

In an operational embodiment, the paint spray nozzles are in a horizontal one Plane, while the web 39 moves in a vertical plane. However, the positions the printing unit and the moving web have to be swapped with regard to the horizontal and vertical planes, if it turns out that only unsatisfactory results can be achieved, when the paint droplets are ejected through the paint spray nozzles against gravity. Each of the paint spray nozzles 38a-38e lies in a plane normal to the plane of the moving ones Lane 39.

3 illustrates a paint spray printing system with three printing units 38, 38 'and 38 ". Each of the printing units 38, 38 'and 38 "has five paint spray nozzles, each with 38a, 38e, 38a'-38e 'and 38a "-38e", respectively. The movable track 39 is at the The illustrated embodiment is driven in the vertical direction by drive rollers 41a, 41b, as shown in FIG. 3. The bracket for each of the printing units 38, 38 'and 38 "is respectively not shown in detail in FIG. 3 in order to avoid overloading the drawing. The printing units can be fastened by a suitable bracket so that they are in the correct position Distance assignment with respect to the moving web 39 are.

In Fig. 3, the main printing cylinder 40 is shown in operational assignment to the printing and drive roller 41a. The relationship between the printing cylinder 40 and the printing roller 41a and the printing units 38, 38 'and 38' '' should only be understood as an exemplary embodiment. The main pressure cylinder 40 can also continue in the forward direction of the moving web 39 be arranged below than in the illustration in Fig. 3. It should also be emphasized that the main pressure cylinder 40 in the direction of web guiding flow also in front of the printing units 38, 38 'and 38 " can be arranged. The mechanical format head or format start on the main head cylinder

40 is particularly indicated in FIG. 3. There is a slot offset from the mechanical format head

41 available, via the electrical format head pulses through a suitable optical coding circuit can be generated in a known manner. Around the periphery of the master cylinder 40 a number of slots 42 is provided to a fixed number of clock or Generate timer pulses with each revolution of the master cylinder. With the one described here Embodiment 2,500 of the slots 42 are provided. The slots 42 is for creation appropriate electrical pulses assigned to an optical encoder. Of the

509810/0741.

electrical format head impulses as well as the series of 2,500 impulses per revolution of the printing cylinder 40 get as input signals to the connection or connection circuit to ensure the necessary timing functions for the operation of this circuit. aside from that is a converter for generating clock pulses for the connection unit for one at a time Fixed number of pulses per inch of web advance. This converter is not shown in Fig. 3, but it can be designed as a known speed converter as normally used for display drive and translation units in printing presses speed can be used.

The distance between the printing units 38, 38 'and 38 "can be used to ensure a desired variable data printing format towards the through the main pressure cylinder printing forms can be changed. It should also be emphasized that the lateral distance of the Printing units 38, 38 'and 38 ", if desired, in a direction transverse to movement of the Web 39 can be adjustable, whereby the by the respective printing units in relation generated on the form or the forms or the templates on the main printing cylinder Pressure can be adjustable.

With each of the printing units 38, 38 'and 38 ", which are in a fixed spatial assignment to the Master pressure cylinder 40 are supported, the system has a format depth selection for the operator on, the terminal unit automatically generating the character-marking pulses adjusts to ensure that the pressure is in the correct allocation according to the Format depth is selected.

4 shows an example of a matrix or matrix division for a total of sixty-four alpha-numeric characters. As this figure shows, each alpha-numeric character is generated by and within a 5x7 matrix, which will be explained in more detail in the following illustration. Each paint spray nozzle is able to display any of the sixty-four alphanumeric characters shown in FIG. 4 to generate. It should be emphasized that the matrix division in FIG. 4 is only to be understood as an example and, of course, other divisions can also be provided.

The theory on which the determination of the release of paint droplets is based is initially brief explained before the detailed illustration of the circuit for correcting the format header

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Pulse in adaptation to the web speed started with reference to FIGS. 5A and 5B becomes: A first counter continuously counts impulses, one directly related to the web speed have proportional pulse train. A second, through a free-running stable oscillator operated counter serves as a monitoring or control for the first counter to a determine a certain counting period of the first counter. The first counter is then reset to 0, and triggers a cyclical counting process for consecutive fixed counting periods. The number of pulses counted by the first counter corresponds directly the speed of the moving web and is used for each cycle of the counting process continuously adjusted. The counting period is set so that the relevant Interval is shorter than the time it takes for the speed of the moving web to change could. One of the factors that play a role in changing the path speed, is the inertia of the press, which is considerable, and this means that the web speed cannot change suddenly in a short period of time. Another factor is the accuracy of the press equipment and the circuitry discussed below also corrects for errors in the speed of the press drive mechanism.

The format header control is explained below first:

With the printing device according to the invention it is possible to start the printing process using the paint spray nozzles to different speeds of the web in the range of approx. 214m / min. adjust to essentially 0 m per minute. It is necessary to set the release time for the color droplets to vary so that they exactly match the different web speeds is adapted.

When printing using paint spray nozzles, there is a certain amount of time between take into account the emergence of the paint droplets at the individual spray nozzles and the moment at which the droplets hit the web. It can be assumed that the distance between the nozzle and the web and the speed of the out of the paint spray nozzles emitted ink droplets are essentially constant. The time period for transmission the droplet of paint from the nozzles onto the moving web is short, occasional on the order of a few milliseconds. At high printing speeds, the web

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Movement during the droplet transfer time is decisive, with the web doing a Traveled about 2.5 cm (1 inch) while at slow print speeds the actual advance of the web can be negligible. It is therefore evident that the triggering of the paint droplet emission from the spray nozzles is a critical factor represents the safest I ment of the touch contact in the correct position on the track, and regardless of the web speed, if precise alignment at the same time of the paint spray pressure is desirable at all web speeds.

The data detected by the first counter unit for each counting operation are converted into a line control signal implemented to discharge the ink droplets against the web to ensure their correct contact at the desired points on the track. This transmission is carried out by a third counter causes its output signals to a logic and digital decoder circuit arrive, which only registered a predetermined number of pulses, such as the Calculated maximum number in cm or inches that the path travels during the flight of the droplets, multiplied by the number of pulses per cm or inch of web advance that are detected by the first counter. Such a calculation leads to a maximum number of pulses that can occur during the flight of the droplets.

This circuit is also designed so that the time or the point of time of the droplet release can be changed according to the desired format depth, thereby releasing the droplets to be able to adapt to the respective printing cylinder. This format header circuit is also explained in detail below. However, it should be noted at this point that that the format head circuit a pulse to trigger the counting process at the third Counter delivers up to a preset maximum count value. The one through the first two Data received from the counter about the web speed are used to preset the third Counter to an initial value that is directly proportional to the path speed. The third The counter then starts up and starts counting with the trigger pulse from this initial value and counts the clock pulses depending on the web speed up to the preset one maximum count is reached. At this point in time it triggers a control signal, which is used to determine the release of the paint droplets from the paint spray nozzles.

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Suppose the first counter counts for 12.5 milliseconds. Will continue like this assumed that per inch (= 2.54 cm) of web advance at one web speed from 213 m / min. 120 pulses occur, the first counter counts a number of pulses, which are can be determined by the following equation during the aforementioned time period:

213 m / min. = 355 cm / sec. 355 cm / sec. χ 120 pulses / 2.54 cm χ 12.5 ms χ = 2,100 pulses

From knowing the speed of the paint droplets and the distance between the paint nozzle and the path can be calculated that it is at a maximum path speed of, for example 213 m / min, is required, the paint droplets about 14.8 mm in front of the desired To release the pressure point on the web, i.e. the release time corresponds to the specified Web speed at a distance of 14.8 mm from the relevant spray nozzle. The calculation can be made through an empirical determination, i.e. through actual measurement the displacement of the ink droplets at a web speed of 213 m / min, assuming confirm the above-mentioned fixed parameters. It is thus possible from the aforementioned Specification, namely the 120 pulses per 2.54 cm web feed and one shift of the web droplets of 14.8 mm to determine the number of pulses up to that of the mentioned Third counter must count to get the ink droplets at the correct time at a web speed of 213 m / min. The following results from the calculation:

Number of pulses = 14.8 mm χ 120 pulses / 25.4 mm = 70 pulses

In the embodiment described here, there is an optical encoder with respect to the plate cylinder arranged so that the format head pulses are 14.8 mm ahead of the actual mechanical Position of the format head (on the impression cylinder). This is in Figs. 3 and illustrated. From the previous description it is already known that the color droplets from the spray nozzles at a web speed of 213 m / min. 14.8 mm in front of the railway point) must be released, which is aligned with the nozzle in question at this point in time. For maximum web speed, the third counter is therefore initially set to that pulse

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preset counter value that corresponds to the maximum path speed at the above given example to 70 pulses, which means that there is no delay in the release of the relevant color droplet occurs. From the description given so far it can be seen that by approximate presetting of the third counter, the time of the droplet release can be determined for each path speed. Referring to Fig. 13, the Distance Y for the format head position of the encoder for web speeds of less as 213 m / min, determine as follows:

.. ljo web speed (m / min.)

Y _AL,, = 14.8 mm χ - T ^

Distance 213 (m / min.)

From the discussion above, the number of times to be initially preset in the third counter Determine impulses as follows:

_v , -τη ι ι orbit speed (m / min.)

Y ₁ . = 70 pulses χ

Impulses ^r / 13 (m / min.)

A counter circuit for generating correction pulses at different web speeds, as mentioned here to explain the operation of the speed correction circuit has been previously proposed (U.S. Patent Application Serial No. 322,534, filed on January 10, 1973).

With the device according to the invention, printing with color nozzles can also be carried out with regard to the format depth (i.e. the size or dimensions of the shape or format on the impression cylinder) adjust and align. The plate printing cylinder is illustrated in FIGS. Plate cylinders have different dimensions and different circumferences. For the purposes of the present description it is assumed that the printing or press cylinder measure 43.18 cm in circumference. A common format size corresponds to a full For example, processing a 21.6 cm format, i.e. a format depth of one. A format depth of two can thus be achieved by one on two separate halves of the cylinder plate arranged 21.6 cm format reproduce, so that with each revolution of the plate cylinder 2 forms are printed. A format depth of three would correspond to a subdivision of the plate cylinder in three such formats, a format depth of four a division into

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four such formats etc. correspond. The format depths are illustrated in FIG. As mentioned before, the format head control provides a pulse to start the counting process at the third counter mentioned to take into account the different format depths to provide, so that the color spray printing is also adapted to different sized formats can be.

In order to be able to carry out these functions, the format head control needs certain Timing data. According to FIGS. 3 and 13, as mentioned, a time is compared to the actual Electrical format head pulse offset (mechanical) format head on plate cylinder 40 (CTOF pulse) with each revolution of the plate cylinder through a suitable transducer generated, for example via a slot 41 which is part of an optical encoder. Through others Transducer means, such as the slots 42, which are part of a further optical converter, additional timing pulses are supplied. For the purposes of the embodiment described here wise the plate cylinder 2,500 equally spaced slots 42, distributed over its periphery, so that with each revolution of this plate cylinder 2,500 Pulses are generated. Depending on the speed of the web being moved forward also generates clock pulses. For the purposes of the following description it is assumed that that the clock pulse sequence, which is dependent on the web speed, is 120 pulses per 2.54 cm web feed. Such impulses can be different in a known manner Generate kind. For example, the web speed can be set directly via a gear train detected in the printing press drive mechanism and by a suitable electrical transducer can be converted into impulses. The construction of arrangements for generating the mentioned electrical format head impulses that generate 2,500 impulses per revolution of the printing cylinder as well the 120 pulses per 2.54 cm of web advance are known, so that to explain the invention a precise description of these units can be dispensed with here.

The format head controller will now be described in detail with reference to FIGS. 5A and 5B explained:

The electrical CTOF pulse of the optical encoder associated with the plate cylinder 40 becomes delivered to terminal 60. The CTOF pulses are used as trigger pulses for the speed

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digkeits correction counter and used as clearing impulses for the format depth counter. These pulses pass through an OR element 62 (AND element with four common inputs), an OR element 64 (NAND element with two common inputs) and inverters 66, 68, which contain a Schmitt trigger. The pulses generated by the circuit described below for triggering the operation of the format head control circuit are supplied by the computer command SYRT via a NOR gate 70. The CTOF pulses at terminal 60, together with the selected outputs of a digit or number decoding circuit (which is described further below), are transmitted via format head switches (TOF switches) 1, 2, 3, 4 in the lower area of FIG. 5A, these switches being selectable by an operator. The CTOF pulses reach a contact of the TOF switch 1 via a NAND gate 72; to the TOF switch 2 via an inverter 74, the NOR gate 76 and the NAND gate 78; to the TOF switch 3 via the inverter 74, a NOR gate 80 with four inputs and a NAND gate 82, and finally to the TOF switch 4 via the inverter 74, the NOR gate 84 with four inputs and the NAND gate 86.

The plate cylinder circulation pulses (PCR pulses) arrive via terminal 88 to counter clock pulses provided via an OR gate 90 (NAND with four common inputs), a NOR gate 92 (NAND with two common inputs), which includes a Schmitt trigger, and inverters 94, 96 to respond to the clock pulse inputs of serially connected binary counters 98, 100 and 102 to arrive. The outputs of the counters 98, 100, 102 are through a digit decoding circuit is decoded, which has the following structural units and how follows works:

Certain outputs of the binary counters 98, 100, 102 are inverted by inverters 104, and the outputs are together with selected output values of the binary counters 98, 100, 102 as inputs for digit decoding circuits 106, 108, 110, 112 and 114 are available posed. The inputs to the digit decoding circuit 106 are such that the number 1 250 is decoded; the input of the digit decoding circuit 108 is determined so that the number 833 is decoded, and the input signals for the digit decoding circuits 110, 112 and 114 are also determined to decode the numbers 1,666, 625 and 1,875, respectively will. Since the pressure cylinder is distributed over 2,500 impulses, it is easy to see

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"" Ιο ™ ·

that the decoders 106-114 decode pulses respectively, the 1/2, 1/3, 2/3, 1/4 and 3/4 correspond to the circumference of the printing cylinder. The outputs of the digit decoders 106, 108, 110, 112 and 114 are input to NOR elements 115, 116, 117, 118 and 119. The The output of the NOR gate 115 (corresponding to 1250 pulses) is used as an input to the NOR gate 76 and 84 given. The output of NOR gate 116 (corresponding to a count of 833) reaches the NOR element 80 as an input. The output of the NOR element 117 (corresponding to a count of 1,666) is given as an input to the NOR element 80. The output of the NOR gate 118 (corresponding to a pulse count of 625) arrives as the input to the NOR gate 84. And finally the output of the NOR gate (corresponding to a pulse count of 1,875) connected as an input to the NOR gate 84.

From the description given so far it can easily be seen that the outputs of the NOR gates 72, 78, 82 and 86 supply pulse trains which _{correspond to format depths of I 7} 2, 3 and 4, respectively. The corresponding pulse trains at the outputs of the TOF switches 1, 2, 3 and 4 are inverted by an inverter 116a and are used for monitoring and control functions, which are explained in more detail below.

The circuit that has the mentioned number of decoding circuits including the inverter 104 and the connection of the binary outputs of the binary counters 98, 100 and 102 for implementation the required number or digit decoding is so well known that a single circuit diagram in connection with the description of the invention is dispensable, since the person skilled in the art If necessary, a suitable number decoding circuit can be set up in order to convert the known to obtain the above-mentioned decoding functions.

To properly set counters 98, 100 and 102 so that an accurate correction compensation occurs when format depth two is selected, for example, it is necessary to use the computer SYRT pulse from the NOR gate 70 to a phase control flip-flop 118a to thereby to prevent the possibility of a print release on the second half of the plate cylinder. The SYRT control pulse clears the flip-flop 118, while the CTOF pulse switches the flip-flop 118, then in turn the counters 98, 100, 102 via the output of an AND element 120 clears. The other input of AND gate 120 is with the SYRT pulse or the CTOF pulse

509810/0741 / 19

applied to the corresponding inputs of the NOR gate via the inverters 122 and 74, respectively 124 must be entered.

The SYRT computer command as well as other data and control signals come as input from the Computer produces trigger circuit 130 in the following way: The format head control is made using the IUAX control signal and the first six bits, i.e. bits EO E5 the computer collective output line E is addressed. The mentioned address bits arrive to NOR gates 132, 134, the outputs of which together with the control signal IUAX on Get NAND gate 136 with three inputs. The output of NAND gate 136 becomes inverted by the inverter 138 and thus provides an input for a NAND gate 140 four entrances. The other three inputs of this NAND gate 140 are through external control commands (EX commands) applied from the computer via the computer data bus, by bits EB6, EB7 and EB8. The output of the NAND gate 140 comes together with the bit EBIl and the control signal FRYX from the computer - as an input on NOR gate 142, the output of which forms the input for the NOR gate 70, together with the computer control signal SYRT to trigger the format depth switch and the circuit to correct the CTOF pulse (modified by the format depth switch). This is also explained further below.

The clock pulses CP for the line unit are generated by the clock pulse generator 150. A transducer input signal of 120 pulses / 2.54 cm is delivered to terminal 152 and reaches an OR gate 154 (AND with four inputs connected together), a NAND gate 156, which contains a Schmitt trigger, and the inverters 158, 160. To trouble when reading the circuits to clarify the logic circuit of the connection unit avoid, the clock pulses are designated CP in the entire circuit diagram of the connection unit.

Referring to Figs. 5A and 5B, the counter circuitry for generating the Corrected CTOF pulses are described in detail: The clock or CP pulses arrive the clock pulse inputs of flip-flops 162, 164, 166 in a divide-by-five circuit 160. The Ö outputs of the flip-flops 162, 164 form the inputs for OR gates 166,

509810/0741 * / 20

168, and the outputs of these elements reach the J input via a NOR element 170 of flip-flop 166. The Q output of flip-flop 162 controls flip-flop 164. The Q output of flip-flop 166 is connected to the J input of flip-flop 162. The Q output of flip-flop 166 corresponds to 1/5 of the CP input on divide-by-five counter 160. The flip-flops 162, 164 and 166 are reset by the SYRT command.

The output of the flip-flop 166 becomes the input for the CP input of the binary counter 168, the Part of a counter 169 is. Another counter 171 comprises the binary counters 170, 172, the the pulses of a 10 KHz oscillator 174 count cyclically, so that a period of 12.5 ms for sampling the divided pulses from the flip-flop 166 to the counter 169 stand what happens in the following way. The output of the generate every 12.5 ms Binary counter 170, 172, inverter 176, NAND gate 178, inverter 180, des NAND gate 182 and the inverter 184 a pulse output to gate 182, which also by the CTOF pulse from the TOF switches described above, adapted to the format depths is controlled. The counter 169 is reset by a pulse output, the is generated by the NAND gate 186 and the NAND gate 188. At the other entrance of the NAND gate 188 is the command signal SYRT. The inputs of the NAND gates 178 and 186 are properly selected by inverter 176 so that the NAND gates 178 and 186 deliver a pulse every 12.5 or 12.7 ms. As already mentioned, this number decoding circuit is known. The value of 12.7 ms is useful because the binary counters 170, 172 each count up to 128, and then fed back (to a new counting process) are. This gives the necessary time delay for resetting the counters 169 and 171.

The last counting stage of the counter 168 is connected to the CP input of the counter 188. The binary count values stored in the binary counters 168, 188 of the counters 169 are through the pulse output of inverter 184 after every 12.5 ms in four-digit fixed or Lock memory 190, 192 keyed in. The in these retention memories 190, 192 Stored information about the web speed is entered in the binary counters 194, 196 of the Counter 197 is reloaded by the same pulse every 12.5 ms. This will make the binary counters 194, 196 preset every 12.5 ms to the respective path speed data.

509810/0741 / 21

The path speed CP pulses are sent to the incremental binary counters 194, 196 by means of of NAND gate 198 (FIG. 5A) controlled by the Q output of flip-flop 200 and that the adapted format depth CTOF pulses from the aforementioned TOF switches over line 201 receives. Have the binary counters 194, 196 a maximum When the preset count is reached, a pulse appears at the NAND gate 202. The maximum The preset value corresponds to the correct color droplet release at maximum web speed required number of pulses.

The maximum preset count is determined by the number decoding circuit that uses the Inverter 204, and the selected inputs from binary counters 194, 196 and the NAND gate 202 receives the necessary input pulses from the inverter 204 and the Binary counters 194, 196 received. The pulse output at the NAND element 202 corresponds to a speed-corrected one CTOF pulse, which is used in the connection unit as a basic timer pulse is used to provide STR1 and STR2 character print control signals as well as other control signals to generate, which is explained in more detail below. The binary output 64 on the counter 196 is used to switch the flip-flop 200 (Fig. 5A) to the CP input to interrupt third counter 197.

The head control - common address control circuit:

The system requires external control commands from the computer to make the head controls ineffective or to take effect, and to stop or close the compensation for the paint spray nozzles start. The external control commands INACTIVE, EFFECTIVE, STOP EQUALIZATION and START EQUALIZATION is applied to the connection unit in the following manner via the circuit shown in FIG. 6. The address or device address for the head control is set by NOR gates 202, 204 and a NAND gate 206 are decoded. Each of the commands INACTIVE, EFFECTIVE, STOP BALANCING and START BALANCING is supported by a special code or Keys 0, 1, 2 and 3 are reproduced. The device or device address at the output of the NAND gate 206 activates a binary-decimal decoder 208, so that the EX command bits from the computer output line a writing of a key 0, 1, 2 or 3 in the Decoder 208 enable. The respective keys 0, 1, 2, 3 go to inverter 210,

509810/0741 ^{/ 22}

212, 214 and 216 and their outputs are in turn on NAND gates 218, 220, 222 and 224 led. The NAND gates 218-224 are activated by a pulse from the NAND gate 226 effective via an inverter 228. The input of NAND gate 226 has the computer control signal FRYX and data from the data collector EBIL. The external computer commands INACTIVE, EFFECTIVE, STOP ALIGNMENT and START ALIGNMENT as outputs of the NAND gates 218, 220, 222 and 224, if the address signal IAUX together with the control signal FRYX is received by the computer. The symbols D and E correspond to INEFFECTIVE = DISABLE and EFFECTIVE = ENABLE as described above, and the symbols in FIG. 6 are uniform for the entire connection unit.

The head controls explained in more detail below are activated by the EFFECTIVE signal E triggered, which is applied to the clock pulse input of the control release flip-flop 236. The flip-flop 26 is set by the output of the AND gate 230, which is based on the computer control signal SYRT and the EFFECTIVE signal D responds. The Q output of flip-flop 236 is the EFFECTIVE signal El, which is used to switch on a special circuit within the Connection unit is used, which is explained in more detail below.

The device address signal (GA signal) is available as an output via an inverter 234, i.e., as a control function for the main head controller, which will be detailed below will be explained.

The STOP BALANCING and START BALANCING signals are sent to the main head control (Fig. 8) and the head controls 2, 3, 4 and 5 (Fig. 8), their respective functions as well are explained in more detail below.

The requirements for the STOP AUSGLEICH and START AUSGLEICH commands are clarified in connection with the description of the electronic circuit of the nozzle control. Shortly before the actual printing process, however, the operator specifies that the program is running properly using a questionnaire checklist presented by the computer on the CRT display is reproduced to the operational monitoring. The operator answers the questions of the computer in order to give it the necessary information to complete the pro-

509810/0741 / ²³

to give gramms. During this setup of the computer program, the software operates an automatic cycle for the nozzle operating functions via start and stop compensation. This control function and its structure to carry out the monitoring and control of the Systems is also discussed in detail below. The STOP and START commands EVALUATION involves checking the nozzles to make sure they are working properly. The computer ignores the nozzle control electronics and operates a button or Sensing device in the collector of each of the nozzles, and if the compensation (for later consideration the web speed) is correct for each of the nozzles, the nozzle control electronics give a message to the computer so that it is informed that the nozzles are ready for printing.

Scanning the nozzles - SERX response:

The scan b, zw. The nozzles are checked using the connection unit in the following section Referring to Fig. 10, the print ready signal ( PRT-RDY) is set to on by the nozzle control via the inverter 240 as an input signal NAND gate 242 given. Since it is assumed for the following description that fifteen If nozzles are present, fifteen lines are also provided to each of the respective nozzles. For the sake of a clearer description, however, only one closer look at these lines. A computer code signal is on the computer connection lines EBo, EB7 and EB8 are available as input signals for a NOR element 244. The remaining one A suitable code key signal to identify each of the fifteen nozzle controls is applied to the input of the NAND gate 242. This code signal is on the computer data lines EB3, EB4, EB5 and EBO, EB1 and EB2 delivered, this Signal represent inputs for the NOR gates 246, 248, respectively.

The address decoder also has a NAND element 250, which is connected to the respective outputs the NOR gates 246, 248 and the computer interrupt signal IAUX applied is. The output of the NAND gate 250 is reversed by the inverter 252 and is applied as an input to the NAND gate 242 for the respective nozzle for which the relevant Scanning or query line is determined. This indicates to the computer that it is using the

509810/0741 '/ 24

The condition of the nozzle in question can be queried to verify that the compensation is correct is. If the compensation signal is correct, the computer sends a command to the nozzle control electronics, to interrupt further compensation or readjustment for this nozzle.

This command is required because it is not possible to use the paint spray nozzle to print, as long as the adjustment or readjustment continues. If there is a matching error at If any of the fifteen nozzles are detected, the computer will identify that nozzle via the aforementioned scanning line. If such a matching error occurs for one or more of the If nozzles are detected, the computer emits an operating alarm signal. This becomes the operator draws attention to the error and can switch off or interrupt the device in order to prevent the Check nozzles.

The main head control:

The aforementioned external effective / ineffective computer commands can also be used for effective / ineffective - Switching the connection unit, for example during such time periods, to which the printing press is running, but should not be printed because the operator is at the Press is making a setting or other operating functions are being carried out should. In these cases the computer will disable the print head controls. That The last thing the computer does before it starts printing is the effective circuit of all controls. The connection unit has a main head controller, which is the first Controls the nozzle head in a printing unit, one of these control circuits is shown in FIG. 7 for clarification shown in the description. The main head controls for printing units 2 and 3 are similar to those of FIG.

The device address (GA signal), as previously explained with reference to FIG. 6, is reversed by an inverter 234 (FIG. 6), and is passed as one of the inputs to a NAND gate 260 with four entrances. The computer sets the NAND gate 260 with the control signal FRYX and the data line EB14. The outputs of the NAND gate 260 set a flip-flop 262 switched by the computer signal DRYX to a 12-bit counter 264 (which has three 4-bit counters 266, 268 and 270 connected in series) via a LOAD pulse to be conditioned by a NAND gate 272, this in turn by the Q output

509810/0741

/ 25

of the flip-flop 262 and the computer signal DRYX is conditioned. A head clearance count from the computer is then fed into the counter 264 via the computer data connection lines EBO enrolled up to ΕΒΠ. The aforementioned CTOF pulse is generated by an AND gate 274 (whose other input is approximately set by the output of a zero decoder 306 is, as explained below) keyed via an inverter 276 to a flip-flop 278 to be determined. The Q output of flip-flop 278 comes along with the web advance clock pulse CP to the input of a NAND gate 280 to read the content of the counter 264 from gradually reduce the head clearance count stored by the computer.

It is necessary to provide a pressure request signal in the nozzle control electronics, that occurs something before the actual triggering of the printing process, for example to the Build up high voltage for droplet charging. This print request signal becomes 240 impulses t 5.08 cm web advance before the desired point to be printed on the web reached the nozzle in question has given to the nozzle control electronics. A decoder 282 decodes the octal number 360, which corresponds decimally to the number 240, using the octal-decimal decoder logic, the NOR gates 284, 286 and 288. The inputs to the NOR gate come from the counter 266. The inputs to the NOR gates 286 and 288 come from the output of the counter 268. Via inverters 290, 292, 294 and 296 the correct inverted signals generated as inputs to NOR gates 286 and 288. The output of the NOR gate 284 arrives, together with the outputs of the NOR gates 286 and 288 as an input to the Decoder 282. The output of decoder 282 goes along with the computer command STOP COMPENSATION as input to an AND gate 298. A message end signal (EOMS = End of Message Signal), the generation of which is explained below, comes together with the computer command START COMPENSATION as an input to an AND gate 300, the output of which is given together with the switch-on pulse El as an input to an AND element 302. The output of the AND gate 302 sets a flip-flop 304, and the output of the AND gate 298 switches flip-flop 304 to transmit the print request signal to the nozzle control electronics 5.08 cm or 240 impulses of the web advance before the first nozzle is printed onto the web Point to provide. The pressure request signal to the nozzle control electronics is the Command to go to print readiness, to end the calibration mode and to print mode to switch. The value of 5.08 cm (2 inches) is chosen to be for the nozzle control electronics

509810/0741 / 26

to provide the necessary time for the build-up of the high voltage level and the Interrupt adjustment, in which case a maximum path speed of 213 m / min. (700 feet per minute) is used.

Simultaneously with the above-mentioned decoding, the counter 264 further reduces its content by means of the web speed clock pulse CP, which is supplied via the NAND element 280. A zero counter 306 determines the count value zero in the counter 264 via a decoding logic which has the NOR gates 308, 310 and 312 which are connected to the respective outputs of the counters 266, 268 and 270. The output of the zero decoder 306 represents an artificially generated single key pulse (ASTR 1) which triggers the head controls 2, 3, 4 and 5 of the printing unit connected to the main head control. The ASTR 1 pulse arrives at the input of a NAND gate 314. This pulse is also an input pulse for a flip-flop 316 and, via an inverter 320, for a divide-by-twelve circuit 318. The flip-flop 316 is activated by a AND gate 444 (described below) set, and toggled by the ASTR 1 pulse, and its Q output, together with the web speed clock pulse CP, goes to an AND gate 322, whereby the clock pulse sequence in the divide-by-twelve- Counter 318 runs in. The output of counter 318 is decoded by NAND gates 324, 326 and 328. Ten characters per 2.54 cm (10 characters per inch) are provided in each line, ie there are 12 pulses per character if - as provided here - 120 clock pulses are available per 2.54 cm. 14 illustrates the relationship of the first character marking pulses STR 1 and the second marking pulses STR 2. For each STR 1 pulse there are five STR 2 pulses. This means that a total of 1 STR 1 and 5 STR 2 pulses are available for each character. The output of the NAND gate 228 is inverted by an inverter 330 and, together with the Δ signal (the generation of which will be explained in detail below), is input to a NAND gate 332. The output of the NAND gate 332 provides, together with the ASTR 1 pulse, the necessary STR 1 pulses at the output of the NAND gate 314 in order to generate each character in a printing unit through the nozzle under the control of the main head controller. The STR 2 pulses are generated at the output of the NAND gate 326 and each consist of five pulses which determine the monitoring for columns X1, X2, X3, X4 and X5 in the 5 × 7 character matrix of the nozzle control electronics.

509810/0741 ^{/ 27}

The above-mentioned operations of the main head controller for each printing unit run cyclically in the manner indicated. The computer provides the necessary head edge pulses Counter 264 when any information change is required, such as when the Printing at other locations on the form on the printing cylinder 40 is to take place.

The following are the print controls for print heads 2, 3, 4 and 5 of each print unit described in more detail:

For the sake of the simplified description, only such a head controller will be described with reference to FIG. Four such head controls are provided in each printing unit, so that in the presently selected example of an embodiment of the invention with three printing units, a total of 12 of these head controls are present. Each of the controllers 2, 3, 4 and 5 of each printing unit generates ASTR 1, STR 1 and STR 2 pulses. Part of the circuitry in head controllers 2, 3, 4 and 5 is similar to that of the main head controller (Fig. 7) and therefore corresponding parts are given the same reference numerals. In this case, the web feed clock pulses CP are input to AND element 340, which is set on the input side by the Q output of flip-flop 342, which in turn is set by the output of an AND element 344 and switched by the CP input pulses will. The AND gate 344 receives an EFFECTIVE input pulse E ₁ , together with an EOM signal (the generation of which is explained below). By setting the AND gate 340, the divide-by-twelve counter 318 is activated in order to subdivide the signal CP. Decoding logic comprises the NAND gates 324, 326, 328, the inverter 338, the NAND gate 332 and the NAND gate 314 generates the STR 1 and STR 2 pulses in a similar manner to the generation of the print control pulses by the main -Head control has been explained. The aforementioned Δ signal, which is generated in connection with the EOMS circuit for the main head control, is input to the NAND gate 314 in order to interrupt the STR! Pulse generation. The STR 2 pulses are provided at the output of the NAND gate 326 in a manner similar to that previously explained for the generation of the STR 2 pulses for the main head control. The main difference between the head controllers 2, 3, 4 and 5 and the main head controller for a particular printing unit is the counter circuit. The head controls 2, 3, 4 and 5 each have a counter 350,

509810/0741. ^{/ 28}

the binary counters 352, 354 and 356 connected in series. There is a fixed spatial Relationship between each of the nozzles and the spring pressure unit. For the sake of description the distance between each of the nozzles is 63.5 mm (2.5 inches) - see FIG. 2. 63.5 mm χ 120 pulses per 25.4 mm of the web feed results in 300 pulses. This corresponds to that Nozzle lag or distance between adjacent nozzles in a printing unit. In order to the STR 1 and STR 2 pulses of a respective head controller 2, 3, 4 and 5 generate a specific printing unit by counting to 300, this counting process by the ASTR 1 pulse of the immediately preceding head is triggered. That means for them Head control 2 receives the ASTR 1 pulse from the main head control of this relevant printing unit as an input to an AND gate 358a. The other input of the AND gate 358a is set positive, since the NAND gate 274 has not yet been keyed and thus the flip-flop 360a is toggled by the output of AND gate 358a via an inverter 362a. The Q output of a flip-flop 360a clears and triggers the counting process for the CP pulses through the Counters 352, 354 and 356. The counters 352, 354 and 356 are then coded to a binary Octal count increased from 454, which corresponds to a decimal number of 300. The output of the counters 352, 354 and 356 is from the binary-coded octal representation to a decimal value by a known octal-decimal converter circuit transferred in the circuit diagram by NAND gates 358, 360 and 362, inverters 364, 366 and 368 as well as by the inverter 370 is represented. The actual wiring the decoding circuit is not shown to the graphic representation simplify. In addition, such number decoding circuits are known, as already mentioned became. The output of the NAND gate 274 corresponds to the ASTR 1 pulse of the special Head control 2, 3, 4 or 5 and is reversed by inverter 374 to make the Reset divide-by-twelve counter. The ASTR! Pulse from each head control 2, 3, 4 and 5 appear as the output of a NOR gate 376. The ASTR! Pulse of the head control reaches the head controller 3 as an input, whereupon the same operating sequence takes place as described above. Similarly, the pulses ASTR 1, STR 1 and STR 2 become the Head controls 3, 4 and 5 are generated.

The print request from head controllers 2, 3, 4 and 5 of a particular print unit must also be used in front of the STR 1 and STR 2 pulses in a similar manner to the previous one

509810/0741 / 29

With reference to the main head controller. In this case, the binary octal-decimal conversion takes place via the NAND gates 378, 380, 382, the inverter 372 and the Inverters 384, 386 and 388. This number decoding circuit decodes the octal number 74, the corresponds to the number 60 in decimal. The output of the NAND gate 390 comes up as an input an AND gate 292, together with the STOP EQUALIZATION command, to flip-flop 294 accordingly to drive the flip-flop 304 in the main head controller to produce a print request output signal from each of the head controllers 2, 3, 4 and 5. The flip-flop 294 is set by the output of the AND gate 296, which is set by the command START BALANCING and the EOM signal described below is conditioned.

Common head control - end of message (EOM signal):

Each nozzle prints a line made up of thirty-eight characters (including spaces) consists. To determine the printing process through each nozzle it is necessary to monitor what number of characters were printed by each nozzle. The circuit shown in FIG ensures this function for each of the nozzle heads. Since the circuits are each similar, only one of them is described in more detail to show how the characters are counted will.

The aforementioned STR 2 pulses arrive at the clock pulse input of a flip-flop 400. The K input is connected to ground and the J input is connected to +5 volts. The control impulse E at the Q output of the flip-flop 400 comes as an input to a NAND gate 401, whose Output is connected to the clock pulse input of a flip-flop 402. The J input and the K input of this flip-flop 402 are each connected to +5 volts. The clock pulses for the flip-flop 402 cause it to toggle, so that output signals at the terminals Q and Q appear. The Q output of flip-flop 402, along with the Q output of the flip-flop 400 and the STR 2 pulses from the assigned head controller as an input to a NAND gate 404. The output of the NAND gate 404 and the CTOF pulse from the format head control come as an input to a NAND gate 406 to as Register key shift pulse to serve for purposes hereinafter in connection with the nozzle control circuit 10 will be explained. The Q and Q outputs of the flip-flop

5098 10/07 4.1 / 30

are also available at terminals 409 and 411 as additional register key pulses to serve, the purpose of which is also explained below in connection with FIG will.

Binary counters 408, 410 count the number of characters printed by each nozzle in the following described way. Before explaining the counting operation in detail, however, it is necessary to point out that there are two characters in each memory buffer of the nozzle controller each nozzle is stored in the computer facility dedicated to that system will. The data for two additional characters is stored in the memory buffer by the computer each nozzle control is transmitted by the aforementioned CTOF pulse. The CTOF impulse also shifts the two previously stored characters out of the memory buffers each Nozzle control in the assigned print buffer or memory. So are before the actual Printing process at each nozzle four characters are stored in each of the nozzle controls. Therefore, in order to determine the character pressure from each nozzle, it is necessary to use those mentioned counting two character shifts seventeen times. In the head control 1 everyone Pressure unit, the CTOF pulse is transmitted to an input of an AND element 412. The other input of this AND element 412 receives the control pulse E 1. The output of the AND gate 412 serves as an input for the room input of flip-flop 414. The Q output of the flip-flop 414 is connected to the input of the NAND gate 416. The other entrance of the NAND gate 416 supplies the output signal which occurs after the flip-flop 402 is toggled Q reversed by inverter 418. The output of NAND gate 416 is connected to the clock pulse inputs of counters 408, 410. The counters 408, 410 are Binary counter, i.e. the individual outputs of counter 408 correspond to the values 1, 2, 4 and 8, and that of counter 410 has the values 16, 32, 64 and 128. A number decoder 420 is set to decode seventeen STR 1 pulses. For every STR 1 pulse, there are five STR 2 pulses and therefore the number decoder 420 is set to be thirty-four STR decoded 1 pulses to count the number of characters. The necessary inverter circuit is represented in FIG. 9 by an inverter 422. Again, these are the actual ones Connections from the respective outputs of the binary counters 408, 410 not shown, to keep the drawing clear. The decoding circuit and the individual Connections are known. After the number decoder 420 has received the thirty-fourth STR 1 im-

509810/0741 ^{/ 31}

pulse (the seventeenth character shift pulse), triggers its output signal the clock pulse input of the flip-flop 414. This triggers a switching operation of the relevant Flip-flops 414 off at the Q and Q outputs. The Q output then closes the NAND gate 416, sp that the clock pulse inputs (subdivided STR 2 pulses from the Q output of the Flip-flops 402) on the binary counters 408, 410 are prevented. The blocking of the NAND gate 416 also terminates the generation of the Print Data Request Instructions (PDRI) to the PIM input of the computer via the chain of NOR gates 424, 426, 428 (NAND gates with two connected inputs).

The binary counter 430 and the associated circuitry provide two end-of-message (EOM) signals, which are generated in the following manner and for the following purpose: In the main head controls, the pulse output of the inverter is at the clock pulse input of the counter 430 330 (Fig. 7), which generates the STR 1 pulses for the master head control in the chain of logic circuits. For head controllers 2, 3, 4, and 5, the clock pulse input to counter 430 corresponds to the outputs of inverter 338 in each of head controllers 2, 3, 4, and 5 discussed with reference to FIG. The aforementioned output of the number decoder 420 shifts the Q output of the flip-flop 414, which reaches the room input of the binary counter 430. This activates a corresponding counter 430 for the STR 1 pulses from each of the assigned main head controllers or head controllers 2, Z, 4 and 5. As long as four characters remain in each of the memories and print buffers for each assigned USB controller (after seventeen Character shift operations), it is necessary to count four STR 1 pulses in order to terminate the generation of the STR 1 and STR 2 pulses, ie to terminate the print line generated by each nozzle. An end-of-message number decoder 432 detects the count value four in the binary counter 430 / and the number decoding circuit 434 shown as a block diagram supplies the necessary inputs to the end-of-message decoder 432 from the binary outputs 1, 2, 4 and 8 of the binary counter 430 to perform this function. Numeral 434 denotes the inverter circuit used for this number decoding operation. The end-of-message number decoder 432 is connected to the output of a NOR gate 436 (a NAND gate with through-connected inputs) via an inverter 438. The output of NOR gate 436 provides an EOM signal which is transmitted to the PIM input of the computer.

509810/0741 ^{/ 32}

An end-dep message number decoder 440 provides an additional control function which will be explained below. The number decoder 440 is connected to the corresponding outputs of the binary counter 430 (using the inverters 434) in order to be scanned by the third STR! Pulse counted by the counter 430. The output of the end-of-message decoder 440 is connected to the clock pulse input of a flip-flop 442. This flip-flop 442 has been reset by the ASTR! The clock pulse signal from the end-dep. Message number decoder 440 to the input of the flip-flop 442 causes its Q output to toggle and generates the aforementioned Δ signal. The 4 """signal from each of the fifteen head controllers each common end-of-message-circuit of each of the three main-head controllers and the twelve head controllers 2, 3, 4 and 5 in the following way transmission. For the main head controller enters the Λ signal as an input to the NAND gate 332 in FIG. 7, which is blocked so that, to terminate the generation of the sTRL-pulses. Likewise, the Δ signal is at the input of the NAND gate 332 in the head Controls 2, 3, 4 and 5, respectively, are switched as explained above with reference to FIG. 8, whereby the STR1 pulses from each of the head controllers 2, 3, 4 and 5 are terminated.

The EOM output at an associated end of the message number decoder 432 is in the case the main head controller for each printing unit with the input of the AND gate 444 connected in this main head controller (Fig. 7). At the other input of the AND gate is the activation signal E 1. The pulse output from AND gate 444 is on the room input of the flip-flop 316 switched to the operation of the divider 318 and the subsequent End the decoder circuit, which also interrupts the generation of the STR2 pulses (Fig. 7) will.

Each of the head controllers 2, 3, 4 and 5 (Fig. 8) has the EOM output of a respective one End-of-the-message number decoder 432, together with the activation signal E1 the input of the AND gate 244. The pulse output of the AND gate 344 is the room input of flip-flop 342, thereby enabling the operation of divider 318 and subsequent and the logic circuit shown in FIG. 8 is terminated to thereby also generate

509810/074 ^1/33

Generation of the STR 2 pulses from each head controller 2, 3, 4 and 5 to each printing unit break up.

The nozzle control: Supply of the coded alphanumeric data to the nozzle control circuit:

In the embodiment of the invention described here, there are five nozzles per print head, and a total of three print heads are provided. The nozzle control circuit performs the function of the receptacle the data to be printed from the computer as well as the transfer of the data to each of the Nozzles in each print head so that each line of the desired variable information in Specified orientation with respect to the format on the printing cylinder 40 is printed out. Fifteen nozzle control circuits are provided in the system described here. One Fig. 10 shows a typical circuit of this type.

Each alpha-numeric character is represented by a seven-bit code in ASCII code format. Two characters at a time are written in each nozzle control circuit. One character appears on the computer buses EBO through EB6, and another Characters are transmitted via the bus lines EB8 to EBl5. The character data on the buses EBO to EB6 are written into buffer memories 450 to 452. The other sign is temporarily stored in buffers 454 to 456. The character information is stored in the Buffer memories 450 to 456 are keyed in by a flip-flop 458, which is activated by the output signal of a NAND gate 460 by the computer signal FRYX the signal on the E-busbar EB14 and flushing the output of the previously described address register. The computer signal DRYX is fed to the clock pulse input of flip-flop 458, the Q output of which is the data from the busbars EBO to EB 15 into the buffer memory 450 to 456. The pushing impulse at terminal 407, which is triggered by the CTOF pulse of the NAND gate 406 (previously under with reference to Fig. 9) is generated, the character information for two characters is scanned a point in time from the buffer stores 450 to 456 into the respective pressure stores 462, 464, 466 and 468 via port 470, inverter 472 and port 474.

The character data in the print memories 462 to 468 are changed alternately in the following manner pushed out of these memories: The previously explained memory or register strobe pulses

509810/0741 ^{/ 34}

appear on terminals 409, 411 in FIG. 9 and are fed to the respective inputs of gates ^ 76 and 478, respectively. As explained, the pulses at terminals 409, 411 correspond to alternating STR2 pulses from an associated main head or head controller. As also already explained in FIG. 9, a PDRI pulse is additionally transmitted to the PIM input of the computer in order to request new character data. This takes place every time the character data is moved between the pre- or intermediate memories and the print memories.

The pulses at terminals 409, 411 from the corresponding Q or Q output of the flip-flop 402 in FIG. 9 alternately control a number of AND gates 480, 482, 484

486 etc. to alternately read the character output data from the print memories 462, 464 and the pressure memories 466, 468 via additional AND gates 488, 490 etc., OR gates 492, 494, 496 etc. and line amplifiers 498, 500, 502, 504, 506, 508 and 510, to provide seven bits of information representing each character on the data lines Ll to L7 correspond. This information on lines Ll to L7 then arrives as Input to the nozzle control circuit for generating the necessary control voltages in the Loading tunnel of the assigned nozzle for each character. It should be noted that not the entire Logical switching chain at the output of the pressure accumulator 462 to 468 and the lines Ll to L7 is shown in the drawings. Only one sufficient for illustration is shown in each case Number of ports and connections between the outputs of the pressure accumulators 462 to 468 and the lines Ll to L7, so as not to reduce the clarity of the drawing to affect. For the expert, the addition of the additional logical ones is necessary Gates for the respective outputs of the pressure accumulator 462 to 468 possible to achieve the necessary To obtain character data on lines Ll to L7. The character data output at each Nozzle control is available in ASCII code.

In the head control circuit explained with reference to Fig. 9, the logic circuit 309, the output of which is cleared by the flip-flop 400 and which receives the command INEFFECTIVE, and the output of inverter 330 in the respective main head controller and head controllers 2, 3, 4 and 5 (Fig. 7 and 8) ensure the correct state of the flip-flop 400. The logic circuit 309 differs in the main head control and head controls 2, 3,

509810/0741 / 35

4 and 5. The logic circuit 309 is ^f for the main control Kop in Fig. TIA shown, while Fig. ΠΒ the logic circuit 409, the head controllers 2, 3, 4 and 5.

The links between the individual figures of the connection unit circuit described above can be seen from FIG.

In Fig. 13 are the relationships of the format depths on the plate cylinder, along with the electrical format head (CTOF pulse) and the mechanical format head switches (TOF switches) and the clock slots.

14 illustrates the relative timing of the occurrence of the PRINT REQUEST signal, the PRINT READY signal, the STR1 and STR2 pulses, the status of the data lines L1 to U and the web feed clock pulses CP. As far as the CP pulse changes with the web movement, the signals mentioned above and shown in FIG. 14 are also shifted in time, but the order and time sequence in which they are generated relative to one another is the same for all web or press speeds and corresponds to Representation according to FIG. 14.

The nozzle control electronics:

15 shows the essential components of the nozzle control electronics in a block diagram and applying the signals generated by this control circuit to various structural units a nozzle shown in the lower part of FIG. A matrix generator 550 receives the character setting command in ASCII code on the data lines Ll to L7 of the connection unit (Fig. 10). The matrix generator 550 is also supplied with timing pulses STR1 and STR2 for character generation from each of the main head controllers and the head controllers 2, 3, 4 and 5 fed to the connection unit. With the system described here are - because there are fifteen nozzles, each of which is able to create a separate line to print alpha-numeric characters - to provide fifteen matrix generators 550, which each have individual character data on separate data lines Ll to L7 and Character data clock control signals STR1 and STR2 from those associated with the respective nozzles

509810/0741 / 36

Head controls are fed.

Each matrix generator 550 generates a train of digital pulses, each pulse being one Color droplet corresponds. The matrix generator 550 also generates clock control pulses and the sequence of digital pulses and the clock control pulses are generated by a digital system converter circuit 552 (video generator) added, which the sequence of digital pulses below Using the clock control pulses converts it into an analog video signal. The output of video generator 552 corresponds to a low frequency video representation for each of the characters that was received by the matrix generator 550 concerned.

The low frequency video character data from the video generator 552 is passed to a final amplifier circuit 554, which has the following basic components: a DU driver circuit, a video amplifier circuit and a high voltage deflection circuit. The nozzle driver circuit provides a 66 KHz sine wave to excite a piezoelectric crystal in nozzle 556, the purpose of which is further discussed below. The 66 KHz sinusoidal signal passes from the video generator 552 to the nozzle driver circuit in the final amplifier stage 554. The video generator 552 transmits the signals PRINT READY and receives the signals PRINT REQUEST, which was mentioned above in connection with the explanation of the connection unit became.

The video amplifier section of the final amplifier stage 554 amplifies the low level of the Video character data from video generator 552 and the output goes to a charging tunnel 558 supplied, in de selected color droplets with one of seven possible charging voltages applied (or no charging voltage received), according to the video character information, generated by the video generator 552 from the matrix generator 550 became. The loading of the droplets to generate the apha-numeric characters continues explained below in connection with FIG.

The 66 KHz excitation of the nozzle 556, along with the pressure of the paint supplied to the nozzle via orifice 557 from a supply of paint (described in detail below), causes the paint to be torn apart into discrete small droplets, and though

509810/0741 / ³⁷

so that about 66,000 droplets are generated per second.

The high voltage from the deflection circuit of final amplifier stage 554 becomes a deflection tunnel 560 (relative to the position shown in FIG on droplets is rotated 90), causing each of the color droplets to deflect a distance which is directly proportional to the applied charge received by the ink droplet, when it passes through the loading tunnel 558. In the illustrated embodiment of the nozzle the ink droplets are deflected from the plane of the drawing in FIG. 15 onto the moving web 39. Those color droplets 559 that are not are loaded with a charge, are deflected in the deflection tunnel 560 and are through the collector 564 and through a vacuum return line 566 into the paint supply system returned.

In the collector 564 a sensor 568 is provided to the scanning of the color droplets during

to ensure the calibration operation of the nozzle. Generally speaking, it is necessary to feel / with the ncntig ^ n phase or the correct balance also occur with the correct Charge to be acted upon. If the correct charge is not impressed on the ink droplets, so must the balancing of the ink droplets by correcting the phase of the supplied to the nozzles 66 KHz vibration signal can be simulated. The technical procedure for this comparison of the ink droplets and a device suitable for this are described, for example, in US patents Documents 3,465,350, 3465,351 and 3,562,761 are disclosed and are assumed and here also only mentioned to improve the understanding and the function of the color droplet adjustment, such as

it is applied to the system according to the invention. It should be emphasized, however, that the circuit and the
/ Methods for droplet sensing and alignment themselves do not form part of the invention.

The color droplet scanning and the adjustment is carried out by an adjustment and droplet sensor 570 in Fig. 15, which determines the alignment signal for the video generator 552, whereby the signals PRINT READY can be generated.

It should be noted that the nozzle spray opening has a diameter of a little more than 1/100 mm (1/2000 inch) and that is the distance between the collector 564 and the moving The web in the system described herein is substantially 1/2 inch.

509810/0741 _{/ 38}

- Jo -

The creation of characters by charging ink droplets:

16A to 16G illustrate the principle or the operating theory for the generation of the video signals provided here, the generation of sixty-four alpha-numeric characters in the matrix division (see FIG. 4) being intended to be generated by the nozzle control electronics. As already explained with reference to FIG. 15, the amplified video signals, which represent the charging voltages, determine a particular character and are fed to the charging tunnel 558. Figure 16B shows the relationship of the thirty-five pulses available to produce a given alpha-numeric character within the 5x7 character matrix. As already described in connection with the connection unit, the STR1 pulses in the nozzle control electronics are used to display each alpha-numerical character in a print line via each of the fifteen nozzles. The STR2 pulses generated by the respective main head controllers and the head controllers 2, 3, 4 and 5 are each assigned to a specific column X1, X2, X3, X4 and X5 of the 5x7 character matrix. The lines are indicated as Y1, Y2, Y3, Y4, Y5, Y6 and Y7 in Fig. 16G, respectively. Corresponding voltage levels are generated within the time interval of each STR2 pulse, which determine the intervals X1 to X5, each corresponding to a row or row Y1 to Y7 of the matrix in the representation selected in FIG. 16A. Thus - if thirty-five pulses are generated by the matrix generator 550 (FIG. 15) - a complete rectangle would be printed out as a result by the relevant printing nozzle, since in the charging tunnel 558 charging voltages for each droplet within the droplet stream, as indicated in FIG. 16C, and would be laid out for each column X1 to X5 of the matrix.

Figures 16D, E, F and G illustrate how the letter E is generated: the matrix generator generated in the nozzle control electronics, in accordance with the STR1 and STR2 pulses and the character data, on lines 1 through 7 from the terminal unit during the XI interval a pulse train to correspondingly for the line positions YI to Y7 consecutive Generate voltage levels. These voltages are transmitted from the video amplifier to the charging tunnel fed. As far as the droplets passing through the loading tunnel are balanced or occur synchronously with the pulses, each of the seven successive droplets, which pass through the charging tunnel during the interval Xl, a correspondingly higher voltage

509810/0741

imprinted. A dotted line is created for column Xl on the path being moved forward, where the charged droplets along an axis transverse to the advancing movement of the web in different Hitting intervals as the droplets pass through the deflection tunnel. in the Interval X2 is only the first, fourth and seventh pulse in this interval from the matrix generator generates and leads to excitation levels in the video amplifier that correspond to the line spaces YI, Y4 and Y7 correspond. This pulse generation by the matrix generator is used for the Intervals X3 and X4 repeated. In the interval X5, only the line locations Yl and Y7 generated voltages by the pulse train shown in Fig. 16E, resulting in the result results in only the first and seventh droplets entering the loading tunnel during this Runs through an interval, a charge is applied. The remaining droplets, viz the droplets 2 to 6 are not charged and therefore not when passing through the Distraction tunnel distracted. Uncharged droplets are, regardless of the interval Xl to X5, are not deflected and enter the collector 564 shown in FIG. 15.

The printing ink system:

17 shows the side view of the printing unit 38 and illustrates the mechanical one Structure and assignment of the paint supply and the vacuum paint return system for one typical pressure unit. The paint is fed under pressure into a multiple feed line 600 from an electromagnetically controlled supply arrangement 602 pressed in, which the color a paint inlet 406 is supplied from a paint supply unit, which will be described below For the sake of simplicity, only one color system is shown and described as far as the individual color systems are identical for each color nozzle unit. The paint for the paint spray nozzle 38c enters the paint multiple supply via a connection 606 600 and passes through a manually operated shut-off valve 608. Before the under Ink under pressure enters the nozzle head 610, it is filtered by a filter 612 and passes through a line 614 to the nozzle head 610 via the connection unit 616. The Color droplets generated by the vibrating transducer do not pass through one in FIG loading tunnel shown and then pass the baffle 612 onto the moving Path 39 or into collector 614, depending on the deflection due to the charge of the droplet in question. As mentioned earlier, the uncharged droplets are carried through

50981 0/07 A ^1/40

the collector 614 collected, and the color collected in the collector 614 is internal Lines and via a vacuum outlet line 616 returned to the multiple line 618 is connected for vacuum return. The ones in every collector on every paint spray nozzle accumulated paint is evacuated via the vacuum return line 620.

The paint supply regulating system essentially consists of a double connection pump, 2 paint containers, two containers for additional solution, a vacuum pump, various caliber tubes, Pipe connections and associated electrical controls. The pump performs the

2 2

Color the print heads with a pressure of 3.36 kg / cm plus or minus 0.0175 / cm. The pump draws the color from one or both of the color memories, either one or both pump connections can be used. The air contained in the paint container is through sucked off the vacuum pump. The remaining vacuum is used to return the paint from the print heads to the memory. The color memories are automatically from Storage for the additional solution refilled. The ink system can be used with suitable low pressure and low vacuum intermediate barriers may be provided to avoid wasting paint in greater quantities Avoid scope.

An exemplary embodiment of the paint supply system is shown in FIG. A Paint container 622 is under a paint trap by a pump 624 through a filter 626 628 and a vacuum line 630 generated vacuum, the vacuum line 630 being a Mouth 632 in the paint container 622, as the figure shows. A memory the additional solution is under atmospheric pressure, and the one to be supplied from this reservoir 634 Color is automatically entered into the color memory 622 via a line 636, a controllable one Solenoid valve 638 and a line 640 added. The solenoid valve 638 is through a Not shown level sensing device in the paint tank 622 is controlled. The paint pump 642 pumps the paint through a valve 644 and a filter 646 from the paint store 622. With 625 is a switch for high vacuum, which is set to about 635 mm Hg, while at 629 a vacuum switch for minimum vacuum is designated, which is set to about 127 mm Hg is set. A vacuum gauge 631 is also provided to show the To be able to read the vacuum in the vacuum line 633.

/ 41 509 810/0741

The paint is pumped to the pressure regulator 650 via the line 648 by means of the pump 642,

2

which is variable between 0 and 4.20 kg / cm. A pressure regulator 652 is adjusted to about 2.45 kg / _C m, so that only then color is released to the associated nozzle 38a to 38e, when the ink pressure in the line 648 exceeds the value of 2.45 kg / cm. A bypass regulator 654 is provided as an additional device for controlling and monitoring the pressure of the paint in the line 648. In order to be able to read the pressure, pressure gauges 656 and 658 are provided at suitable points on the line 648. For example,

2 instruct the pressure gauge 656 to print from 0 to 7.00 kg / cm, while the pressure gauge

2
The 658 prints from 0 to 4.20 kg / cm can be read. The under regulated pressure of about

2 '

2.94 kg / cm of standing color is transferred via the supply and solenoid valve arrangement described above 602 (FIG. 17) to the multiple feeder 600 and then through the manually operated shut-off valves 608a to 608e.

The paint from the collectors 614a through 614e is correspondingly in the vacuum manifold 618, as shown in FIG. 18, and is conveyed from there via the vacuum return 620 and returned through filter 660 to paint reservoir 622. Fig. 18 only shows part of the paint supply system. There is also a reserve system (not shown) present, which is constructed similarly to the illustrated ink supply regulating system.

The ink usable for the printing device can be a water-soluble ink. you the critical characteristic is the viscosity, which should normally be 1.8 cP. The color must be electrically conductive so that the charge can be applied when the Color droplets run through the explained color tunnel. The electrical conductivity of paint is not critical, however, as compensation is provided by changing the charging voltages on the Loading tunnel can be provided. The paint dries by absorption, not through Evaporation, so that the paint is prevented from drying in the nozzles.

/ 42 509810/0741

Claims (8)

lA-45281 PATENT CLAIMS ( 1 J printing device for printing out alphanumeric data on predeterminable and with respect to other data printed by a main printing cylinder aligned positions on a BaHn ₇ advanced at printing speed, characterized by a device (30, 31) for generating command signals and coded data, the correspond to the variable data of a selected multi-line format, a controllable by the command signals and acted upon with the coded data control device (33), the character clock signals (e.g. pulses CTOF, STRl, STR2) according to the sequential position of the alpha-numeric data in the Generated multi-line format, a device (34) for automatic setting of the character clock signals to different web speeds and variable format depth information and by means (36, 37) for printing out the variable data as a function of the character clock signals by projection an independently controllable St roms of ink droplets onto the advancing web (39). 2. Printing device according to claim 1, characterized in that the setting device (34) for the character clock signals at each revolution of the Main printing cylinder (40) emits a format head pulse (ETOF), which before the (physical) mechanical format head of this printing cylinder occurs that a Pulse generator unit (42) first pulses in one of the speed of the Path (39) dependent sequence supplies which are counted for determining the path speed during a fixed period of time by a counting unit, and that the format head pulse can be corrected as a function of these first pulses. / 43 509810/0741 3. Printing device according to claim 2, characterized in that the Control device (33) a unit for setting a number of different Has format depths of the main pressure cylinder (40), and that the adjusting device for the character clock signals a switching unit (Fig. 5A, 5B) for correcting the format head pulse as a function of the desired format depth. 4. Printing device according to claim 3, characterized in that the Counting unit (98 to 102), a counter for recording the first pulses and a means controlling this counter to count during a specified period of time has, and that the switching unit for correcting the format head pulse a Contains counter, which holds the count of the first counter, and the first pulses counts until a predetermined count is reached and generates a signal that represents the corrected format head pulse. 5. Printing device according to claim 4, characterized in that the control device a further device for generating a second pulse sequence with a fixed number of pulses per revolution of the main printing cylinder that the device for automatic setting of the character clock signals a further counting unit for this second pulse contains that a digit or number decoder that of the Number of the format depths corresponding number of pulses determines and that a goal the number of the decoded pulses depending on the format header pulse (CTOF) to the Switching unit scans the excitation of the second counting unit according to the desired Format depth delayed. 6. Printing device according to claim 2, characterized in that the Printing unit (38) a number of mutually offset and along one for the feed movement the web (39) parallel axis arranged printing ink discharge nozzles (36; 556) each independently for releasing a stream of ink droplets (559) are controllable that the control unit has a main or master tax rate and a number of dependent (servo) control sets for controlling at least one / 44 509810/0741 Printing unit, wherein the main control rate controls the spray nozzle, which is the first selected pressure areas on the advancing web (39) opposite, and which the dependent control rates (2, 3, 4, 5) each control a specific one of the remaining spray cans that the main control rate responds to the corrected format head pulse in order, on the one hand, to generate the signals that control the release of paint droplets of the assigned spray nozzle and, on the other hand, to generate second timing signals, so that one of the dependent control rates generates third time switch signals that enable the release of paint droplets through the assigned paint spray nozzles and the controller obtain another of the dependent tax rates, and that the dependent tax rates provide signals for controlling the release of paint droplets by an associated paint spray nozzle and additional timing signals for controlling that dependent tax rate which is assigned to one of the subsequent paint spray nozzles. 7. Printing device according to claim 6, characterized in that the for Control of ink droplet release from the main tax rate and the dependent ones The signals supplied to tax rates are the successive alpha-numeric signals Character indicating primary impulses (STRl), the sequence of which at least in part by the Speed of the moving web (39) is determined, and between the primary pulses lying secondary pulses (STR 2) contain the color droplet stream (559) of the control the assigned spray nozzle (556). 8. Printing device according to claim 6, characterized in that the A device for generating coded data has a buffer and a print memory Storage of consecutive alphanumeric characters within the multi-line format and means for generating a shift pulse from the corrected format header pulse which is those contained in the buffer memory Pushes data into the print memory and stores new data in the buffer memory causes and that the printing unit responds to the output signal of the pressure accumulator. 509810/0741