EP1370416A1 - Methods and devices for operating a pressure unit - Google Patents

Abstract

The invention relates to a method for operating a pressure unit comprising at least one counter-pressure cylinder (03) and a transfer cylinder (04) forming a pressure point therewith. The counter-pressure cylinder is mechanically actuated by means of a first drive motor (06) independently from the transfer cylinder. In a pressure -on- position, the counter-pressure cylinder is adjusted as a guide variable in relation to the power of the motor which drives the cylinder.

Description

description

Method and devices for driving a printing unit

The invention relates to methods and devices for driving a printing unit according to the preamble of claims 1, 3, 5 or 12 and 13, 14 or 22.

When driving cylinders or cylinder groups with separate drives z. B. in satellite printing units process-related processing differences between the cylinder pairs can occur. These are dependent on the starting pressure, the number of active pressure points, the lift strength, the type or even the manufacturer of the lift itself, whether the friction gear is designed in an ingloseless manner or with bearer rings, the bearer ring radii or the overall radial ratio of the friction gear.

This can lead to e.g. T. considerable and, under changing conditions, lead to significantly different power flows between the cylinders or the cylinder groups. This is undesirable because they lead to asymmetries in the power rating, depending on the conditions and mode of operation, to different powers or even to overloads on motors and controllers.

DE 195 01 243 A1 discloses cylinders of a rotary printing press with bearer rings, the bearer rings of the satellite cylinder being rotatably mounted for the purpose of reducing the power transmission.

In WO 00/41887 A1, a compensating friction gear in the form of bearer rings having an inverse radius ratio is superimposed on a friction gear made of process-related friction cylinders. The normal force between the cylinders placed against each other is adjusted so that an amount of a difference in the power consumption of the motors driving the cylinders is minimal. DE 19527 199 A1 shows a drive of a printing unit, wherein a forme cylinder can be driven at different circumferential speeds depending on a contact of the printing forme with an impression cylinder. A peripheral speed different from the impression cylinder exists in a phase of the cylinder rotation in which there is no pressure contact between the forme and impression cylinder.

The invention has for its object to provide methods and devices for driving a printing unit.

The object is achieved by the features of claims 1, 3, 5 or 12 and 13, 14 or 22.

The advantages that can be achieved with the invention are, in particular, that the printing cylinders are handled sufficiently well, which is largely independent of the contact pressure and / or the number of active pressure points, the elevator strength and / or the type or manufacturer of the elevator. With changing configurations of the printing points and / or the extracts, in particular the printing blankets on the transfer cylinders, the print quality is not or only insignificantly deteriorated.

Basically, a suitable, defined difference in the peripheral speed can be determined for different operating modes and / or elevators, e.g. B. stored in a storage unit and depending on the mode of operation / lift during production and maintained.

By means of the regulation according to the invention of a leading or lagging of the rotational speed or the peripheral speed of at least one of the cylinders in relation to at least one cooperating second cylinder depending on the output or The power of the drive motor consumed via the friction gear advantageously minimizes the fluctuation range for the motor or generator power of the drive motor.

The above Regulation can be used particularly in printing units, with several transmission cylinders with so-called satellite cylinders forming pressure points, such as. B. in 5-cylinder printing units, 9-cylinder or 10-cylinder satellite printing units.

It is particularly advantageous to use the above-mentioned regulation for printing units with cylinders rolling on one another without a bearer ring. The satellite cylinder is operated with a lead or lag relative to the cooperating transfer cylinders, depending on the power consumption or output of the drive motor assigned to it. In the case of bearerless cylinders, the power is transmitted solely by the rolling of the cylinders themselves. When changing the configuration, especially when changing elevators on the transfer cylinders, e.g. B. of blankets with different conveying behavior - so-called negative, neutral or positive-promoting blankets - the required generator or motor power on the satellite cylinder is kept within narrow limits by means of the control. Oversizing and / or the risk of overloading controllers and drive motors is thus reduced.

However, the regulation is also suitable for printing units with bearer rings rolling on one another, in which case slippage between the bearer rings is permitted within certain limits (see below).

In order to maintain a desired print quality, selectable items are selected simultaneously with the minimization of the generator or motor power on the satellite cylinder. Upper or lower limits for the deviation of the speed or the peripheral speed from the peripheral speed of the cooperating transfer cylinders. Within these limits, the satellite cylinder is on its minimum absolute power (generator or motor) driven. These limits can be selected differently for different substrates, for different printing processes and different quality requirements. B. for newspaper printing at between ± 0.01% to + 0.05% deviation from production or Peripheral speed of the interacting cylinders.

This regulation is advantageous for printing units whose cylinders are driven in groups or individually by several mechanically uncoupled drive motors: For example, for 9 or 10 cylinder satellite printing units with one drive motor per cylinder, for 9 or 10 cylinder satellite printing units with one drive motor per forme cylinder Transfer cylinder pair and the satellite cylinder (s) or also for 9 or 10 cylinder satellite printing units, each with a drive motor for a group of form cylinder transfer cylinder pairs. Embodiments of the invention are shown in the drawings and are described in more detail below.

Show it:

Figure 1 is a schematic representation of interacting cylinders of a rotary printing press.

2 shows a schematic illustration of a 9-cylinder satellite printing unit;

Fig. 3 is a schematic representation of a 10-cylinder satellite printing unit.

A rotary printing press has a printing point 01 with two together in a print-on position via a web 02, z. B. a substrate web 02, in particular a paper web 02, interacting cylinders 03; 04 on. The cylinders 03; 04 are designed in the example without bearer rings and form a friction gear by means of their rolling surfaces that roll on each other. The first cylinder 03 is used as an impression cylinder 03, e.g. B. formed as a steel cylinder 03 and is directly or indirectly via a drive motor 06, but independently of the second cylinder 04, for. B. a transfer cylinder 04 or a plate cylinder 04 in high pressure or flexographic printing.

The second cylinder 04, for example designed as a transfer cylinder 04, is also directly or indirectly, for example via a transmission, not shown, for. B. a gear, toothed belt or a friction gear, driven by a second drive motor 07. The transfer cylinder 04 can be used individually or together with a third cylinder 08, e.g. B. a forme cylinder 08, or a dyeing and not shown dampening unit. In the example, the transfer cylinder 04 can be driven together with the forme cylinder 08 by means of the drive motor 07 (schematically in FIG. 1).

The second cylinder 04 has an elevator 09, z. B. a printing blanket 09, a rubber blanket 09 or a plate 09, through which the ink is applied to the paper web 02.

In the example, the impression cylinder 03 with a radius r03 and the transfer cylinder 04 with a radius r04 are cylinders 03; 04 executed with so-called double extent, d. H. with a circumference, which two standing or lying printed pages, for. B. newspaper pages. In order to counteract a distortion or shift in the printed image caused, for example, by flexing the elevator 09, the radius r03 of the impression cylinder 03 is made 0.2 to 1 per thousand larger than the radius r04 of the transfer cylinder 04.

However, cylinders 03; 04 single circumference or, for example, the transfer cylinder 04 with a single and the impression cylinder 03 with a double circumference. The width of the cylinder 03; 04; 08 can be single, double, triple or quadruple.

In conventional procedures, the cylinders 03; 04; 08 such that peripheral speeds u03; u04; on the cylinders 03; 04; 08 are almost the same. This is done when using several drive motors 07; 06 usually via a speed control and an "electronic shaft", ie via electronic synchronization.

Especially with bearerless cylinders 03; 04; 08, however, there is a strong mechanical coupling via the lateral surfaces, which is strongly dependent on the type of elevators 09, their properties and on the number of cylinders 04 employed on an impression cylinder 03. For example, rubber blankets 09 of different types or manufacturers indicate when they are unrolled the surface of the counter-pressure cylinder 03 very different delivery behavior:

Negative conveying rubber blankets 09 on the transfer cylinder 04 tend to counterpressure cylinder 03 at the same peripheral speed u04; u03 or speed n07; n06, to be braked while positive-promoting rubber blankets 09 accelerate the jerk cylinder 03 in the direction of rotation. In the first case, the drive of the drive motor 06 for the impression cylinder 03 requires an increased motor power, and in the second case an increased generator power L06.

A regulation to equal circumferential speeds u03; u04 or speeds n06; n07 or a fixed relative angle of rotation does not do justice to the problem with changing conditions.

As shown schematically in Fig. 1, the peripheral speeds u03; u04 the cylinder 03; 04 or the speeds n06; n07 whose drive motors 06; 07 detected and given to a controller 11. The acquisition can take place via separate encoders, via internal motor encoders or in another way. In addition, at least the power L06 of the drive motor 06 on the impression cylinder 03 is recorded and sent to the controller 11.

The controller 11 can be designed in different ways, so that for example everyone the drive motors 06; 07 its own drive control 12; 13, which has a target value n06-target; n07-should for a circumferential speed u03; u04 on cylinder 03; 04 or corresponding speeds at cylinder 08 n06; n07 is assigned via the controller 11. The respective drive control can also be integrated in the control 11. The evaluation of the speeds n06; n07 and the assignment of setpoints n06-soll; n07-soll can be done using software in a computer, the control center or a module of a PLC using a program or hardware.

At the start of production, the drive motors 06; 07 by means of feedback of the actual values for the speed n06; n07 as a reference variable in this way to setpoints n06-Soll; n07 should regulate their speed so that the peripheral speeds u03; u04 of the interacting cylinders 03; 04 are almost the same.

When printing on, i.e. H. the two cylinders 03; 04 are in pressure contact with each other, the circumferential speed u03 of the impression cylinder 03 is varied in such a way that the power L06 of the drive motor 06 decreases in magnitude and ideally takes a minimum. There is a conscious change in the relative peripheral speeds u03; u04 or changes in the relative angular position permitted. This is independent of the passage of a printed image through the nip point, but generally takes place in the pressure contact. The power L06 is now the reference variable for controlling the peripheral speed u03 or the speed n06. Based on the power L06 as a reference variable, for example a changed setpoint for the peripheral speed u03-target or the speed n06-target can be determined and assigned.

In principle, it is also possible to use appropriate differences for different operating situations and / or different elevators

Peripheral speeds u03; to store u04, which is then driven by angle and / or speed-controlled drive motors 06; 07 are complied with. The variation of the speed n06 takes place on the condition that the circumferential speed u03 by a maximum deviation Δu1, z. B. Δu1 = - 0.01% to - 0.05%, under the peripheral speed u04 of the cooperating cylinder 04 (lag) or the production speed u _p and by a maximum of Δu2, z. B. + 0.01 to + 0.05%, is above the peripheral speed u04 of the interacting cylinder 04 (advance) or the production speed u _p . For this reason, the speed n06 or the peripheral speed u03 is still monitored and compared with the speed n07 or the peripheral speed u04 of the second cylinder 04. It is monitored whether the relative deviation .DELTA.u of the peripheral speed u03 from the peripheral speed 04 is still in the above-mentioned permissible interval.

The following applies to the control during production and / or the print-on position:

| Z06 (.DELTA.w) | = Min _local for all <Au | Aul ≤ <Au2>

with: Au = {u03 ~ u04)

The control of the drive motor 06 is therefore not primarily based on the same, constant speeds n06 and n07 or the same peripheral speeds u03 and u04. The control follows a speed n06 along a gradient of the power L06 as a function of the deviation Δu between the resulting peripheral speed u03 and the peripheral speed u04 or

Production speed u _p (for u04 = u _p ) of the interacting cylinder 04.

In the speed range permitted for the variation, which corresponds to the interval [Δu1; Δu2] for the permissible relative deviation in the peripheral speeds u03; corresponds to u04, there may be a relative minimum for the generator or motor power L06. It can U. but also only a monotonically falling or increasing dependency in the allowed interval [Δu1; Δu2] between the power L06 and the Deviation in peripheral speed u03; u04 are present so that the speed n06 and thus the peripheral speed u06 assume the maximum permissible deviation Δu upwards or downwards for the relevant operating state. In this case, too, the generator or motor power L06 is minimized in the permitted interval for the deviation Δu. In this case, the drive of the first cylinder 03 is regulated when the limit value Δu1 is reached; Δu2 using the speed n06 or the peripheral speed u03 as a reference variable. The speed n06 is at this limit value Δu1; Δu2 held as long as the limit value Δu1; Δu2 due to new conditions, e.g. B. depending on the performance 06, can not be left in the allowed direction.

If the transfer cylinder 04 has, for example, an elevator 09 which is negative, ie it “brakes” the counter-pressure cylinder 03, the motor power L06 on the drive motor 06 after the peripheral speed u03; u04 or the production speed u _{p of} the cylinders 03; The speed n06 or the peripheral speed u03 of the impression cylinder 03 is now reduced until either a local minimum or the lower limit value Δu1 for the deviation Δu from the peripheral speed u04 of the second cylinder 04 or Production speed u _{p is} reached, an increase in speed n06 would lead to an increased consumption of motor power L06 in this case.

In the opposite case, when using a positively conveying elevator 09, the drive motor 06 receives pressure cylinders via the friction gear of the cylinders 03; 04 an additional torque and would need u03 in the case of regulation to the same, constant peripheral speeds; u04 increased generator power L06. The speed n06 or the peripheral speed u03 of the impression cylinder 03 is now increased until either a local minimum or the upper limit value Δu2 for the deviation Δu from the peripheral speed u04 of the second cylinder

04 or the production speed u _{p is} reached. A decrease in speed Here n06 would lead to a further increase in the consumption of regenerative power L06.

Such a regulation with regard to the minimum motor or generator power L06 can be preset manually or, in an advantageous embodiment, can also be self-adaptive. The limit values Δu1; Δu2 are dependent on the machine, the substrate, the requirements for the print result and the press configuration and can already be specified as programs which are permanently stored in the control 11 and, if appropriate, can be selected or can be specified via an input device.

In newspaper printing on appropriate paper, both the lower limit value Δu1 (running) and the upper limit value Δu2 (leading) advantageously lie at + 0.01 to ± 0.03%, in particular at ± 0.02%, so that:

| Z06 (Δκ) | = Min local for all {Au \ <0.2% with: Au = («03-« 04)

In practice, the determination and control takes place at specific speeds n06; n07 or peripheral speeds u03; u04 also based on the angular positions of the cylinders 03; 04 or the drive motors 06; 07 and / or their changes over time. In the previously mentioned and in the following, the determination and control of the speeds n06; n07 or the peripheral speeds u03; u04 should also be understood in terms of determining angular positions and regulating the angular positions and / or their changes over time (angular velocities).

A regulation regarding the same peripheral speeds u03; u04 two interacting cylinders 03; 04 corresponds to 03 in the case of cylinders; 04 of the same scope then the corresponding changes in time in the angular positions (the Cylinder 03; 04 or / and possibly the drive motors 06; 07). For different radii r03; r04 the cylinder 03; 04 are u03 when regulating to certain peripheral speeds; u04 to take into account the changes in time in the angular positions or the angular positions themselves in accordance with the radius ratios.

For a control in which a relative deviation Δu in the peripheral speeds u03; u04 the cylinder 03; 04 is permitted or deliberately brought about, in this mode of operation the regulation to the same angular positions and / or their changes over time is at least for the drive of one of the cylinders 03; 04 overridden. The other cylinder 04; 03 can, however, be synchronized with regard to further cylinders, printing units and / or units of the printing press, i. H. to the same peripheral speeds u03; 04, or corresponding angular positions, on maintaining a certain relative angular position and / or on the same temporal changes in the angular positions, are regulated.

2 shows a 9-cylinder satellite printing unit 14 with four possible printing points 01, at which the paper web 02 can be printed in the print-on position. (Printing points 01 and paper web 02 and elevators 09 are not explicitly shown in FIGS. 2 and 3). In contrast to FIG. 1, four transfer cylinders 04 can now optionally be adjusted to an impression cylinder 03 designed as a satellite cylinder 03. The transfer cylinders 04 and the interacting forme cylinders 08 can each be driven in pairs by means of the drive motor 07. In contrast to FIG. 1, between the drive motors 06; 07 and the controller 11 no drive controls 12; 13 shown.

Depending on the number of transfer cylinders 04, the type of lifts 09 (positive, negative, neutral) and the conveying behavior of the type of paper used for the paper web 02, the generator cylinder or the generator cylinder can be operated at a constant peripheral speed u03 or speed n06 Motor output L06 on the drive motor 06 fluctuate considerably again. The drive motors 07 of the transfer cylinders 04 which are in the pressure-on position are regulated via the power supply by means of the actual value of the speed n07 as a reference variable to a speed n07-Soll, which, for. B. the chosen one

Production speed u _p or the peripheral speed u04-should on the

Transfer cylinders 04 corresponds.

The drive motor 06 of the satellite cylinder 03 is also first, in particular before the pressure-on position, by means of the setpoint n06-target specified by the controller 11 to the same peripheral speed u03 = u04, z. B. regulated to production speed u _p .

After the pressure-on position of one or more transfer cylinders 04, the supply of power L06 is no longer the speed n06-nominal or circumferential speed u03-nominal corresponding to the circumferential speed u04, but in the opposite way, using the performance L06 as the command variable, the speed n06 or the peripheral speed u03 is regulated with regard to a minimum motor or generator power L06 of the drive motor 06. The setpoint u03-Soll on the satellite cylinder 03 is z. B. changed by a relative deviation Δu. Again, the boundary condition must be observed that the deviation .DELTA.u of the peripheral speed u03 of the satellite cylinder 03 from the peripheral speed u04 or

Production speed u _p a lower limit value Δu1 (lag) and an upper limit value Δu2 (lead), e.g. B. + 0.02% of the production speed u _p , may not fall below or exceed.

If, as shown in FIG. 3, the two satellite cylinders 03 of a 10-cylinder satellite printing unit 16 are each driven by their own drive motor 06, the regulation regarding the minimum power L06 of each drive motor 06 can be carried out independently. The regulation is particularly also for larger printing units or printing unit groups, eg. B. for two stacked 9-cylinder satellite printing units 14 or for stacked 10-cylinder satellite printing units 16 applicable. In such arrangements, the paper web 02 is four-colored on both sides, or z. B. Both sides can be printed in two colors with full imprinter functionality.

If the transfer and forme cylinders 04; 08 not driven in pairs, but each by means of its own drive motor 07, the drive motors 07 for the forme cylinders 08 and the transfer cylinders 04 are regulated with respect to their circumferential speeds u04-should; u08-target or the speed n07-target for the drive motors 07 according to the above exemplary embodiments for the drive motors 07.

The regulation of a drive motor 06; 07 the cylinder 03; 04 by means of the power L06 as a reference variable is not limited to the counterpressure or satellite cylinder 03 shown in the examples. Likewise, during the production of the satellite cylinders 03, the actual value of the speed n06 or the circumferential speed u03 as reference variable can be kept constant during production Speed n06-should or a constant circumferential speed u03-should be regulated, while the one or more co-operating transmission cylinder 04 is regulated by means of an output, not shown, as a reference variable to a minimum output in the relevant interval.

In the case of individually driven cylinders 03; 04; 08, the drive motor 06 is regulated in such a way that it consumes essentially the same power L06 as the drive motor 07 of the cylinder 04, which in this case is individually driven. For this purpose, a deviation in the peripheral speed u03; u04 accepted within the stated limits. The described regulation in particular avoids a high generator output L06 without the quality of the product being outside a tolerable range. This applies to the use of differently promoting rubber blankets 09.

LIST OF REFERENCE NUMBERS

01 pressure point

02 web, printing material web, paper web

03 cylinder, first, impression cylinder, steel cylinder, satellite cylinder

04 cylinder, second, transfer cylinder, plate cylinder

05 -

06 drive motor, first

07 drive motor, second

08 cylinder, third, forme cylinder

09 elevator, blanket, blanket, cliché

10 -

11 control

12 drive control

13 Drive control

14 9-cylinder satellite printing unit

15 -

16 10-cylinder satellite printing unit

L06 performance

n06 speed (06) n07 speed (07) n06-setpoint, speed n07-setpoint, speed

r03 radius (03) r04 radius (04) u03 peripheral speed (03) u04 peripheral speed (04) u03-target setpoint, peripheral speed u04-target setpoint, peripheral speed

u _p production speed

Δu deviation (u03 - u04)

Δu1 limit, first, lower

Δu2 limit, second, upper

Claims

Expectations

1. A method for driving a printing unit with at least one impression cylinder (03) and a transfer cylinder (04) which forms a printing point (01) therewith, characterized in that the two cylinders (03; 04) acting together and in pressure contact during production are driven with different peripheral speeds (u03; u04).

2. The method according to claim 1, characterized in that the impression cylinder

(03) by means of a first drive motor (06) independent of the transfer cylinder

(04) is driven, and that the counter-pressure cylinder (03) is regulated in the pressure-on position as a function of an input power (L06) of the drive motor (06) driving the counter-pressure cylinder (03).

3. Method for driving a printing unit with at least one impression cylinder (03) and a transfer cylinder (04) forming a pressure point (01) with it, the impression cylinder (03) being driven mechanically independently of the transfer cylinder (04) by means of a first drive motor (06) is characterized in that, in the pressure-on position, the counter-pressure cylinder (03) in pressure contact with the transfer cylinder (04) is regulated as a function of an input power (L06) of the drive motor (06) driving the counter-pressure cylinder (03).

4. The method according to claim 2 or 3, characterized in that, depending on the electrical power (L06) of the drive motor (06), a peripheral speed (u03) of the impression cylinder (03) is changed relative to a peripheral speed (u04) of the transfer cylinder (04) ,

5. Method for driving a printing unit with at least one impression cylinder (03) and a transfer cylinder (04) forming a pressure point (01) therewith, the impression cylinder (03) being mechanically driven independently of the transfer cylinder (04) by means of a first drive motor (06), characterized in that during the pressure contact of the two Cylinder (03; 04) depending on an electrical power (L06) of the first drive motor (06) a peripheral speed (u03) of the impression cylinder (03) is changed relative to a peripheral speed (u04) of the transfer cylinder (04).

6. The method according to claim 2, 3 or 5, characterized in that the control of the first drive motor (06) takes place with respect to an amount of electrical power falling (L06), and that at the same time a relative deviation (ΛU) in the peripheral speeds (u03; u04) of the cylinders (03; 04) or the speeds (n06; n07) of the drive motors (06; 07) lies within a permissible interval.

7. The method according to claim 6, characterized in that the control of the drive motor (06) with regard to an amount according to the minimum power (L06) with variation of the peripheral speed (u04; u04) of one of the cylinders (03; 04) within the the relative deviation (ΔU) of the permissible interval takes place.

8. The method according to claim 1, 3 or 5, characterized in that the second cylinder (04) by means of a second drive motor (07) is driven, and that the transfer cylinder (04) with respect to a predeterminable speed (n07-target) second drive motor (07) or a predefinable peripheral speed (u04-should; u _p ) of the transfer cylinder (04) is regulated.

9. The method according to claim 6, characterized in that the interval for the permissible relative deviation (ΔU) in the peripheral speeds (u03; u04) by a first limit value (ΔU1) ZU smaller peripheral speeds (u03) of the impression cylinder (03) compared to the transfer cylinder (04) and by a second limit value (ΔU2) TO larger circumferential speeds (u03) of the impression cylinder (03) compared to the transfer cylinder (04).

10. The method according to claim 9, characterized in that the first limit value (Δu1) is formed by a maximum deviation (ΔU) of - 0.05 to -0.01%, in particular approximately - 0.02%.

11. The method according to claim 9, characterized in that the second limit value (Δu2) is formed by a maximum deviation (ΔU) of + 0.05 to + 0.01%, in particular approximately + 0.02%.

12. Method for driving a printing unit with at least one impression cylinder (03) and at least one transfer cylinder (04) that forms a printing point (01) with it. First, depending on an operating mode and / or an elevator, at least one of the interacting cylinders (03; 04) a deviation (ΔU) in peripheral speeds (u03; u04) of the two cylinders (03; 04) that is suitable with regard to production is determined and maintained, and wherein during production the drive of the cylinders (03; 04) with that of the Operating situation and / or deviation corresponding to the elevator (ΔU) is applied.

13. Device for driving a printing unit with at least one impression cylinder (03) and a transfer cylinder (04) forming a pressure point (01) therewith, the impression cylinder (03) being mechanically drivable independently of the transfer cylinder (04) by means of a first drive motor (06) is characterized in that during the pressure contact of the two cylinders (03; 04) as a function of an electrical power (L06) of the first Drive motor (06) a peripheral speed (u03) of the impression cylinder (03) relative to a peripheral speed (u04) of the transfer cylinder (04) can be changed.

14. Device for driving a printing unit with at least one impression cylinder (03) and a transfer cylinder (04) forming a pressure point (01) therewith, the impression cylinder (03) being mechanically drivable independently of the transfer cylinder (04) by means of a first drive motor (06) characterized in that during the pressure contact of the two cylinders (03; 04) a peripheral speed (u03) of the counter-pressure cylinder (03) can be regulated as a reference variable as a function of an output (L06) of the drive motor (06) driving the counter-pressure cylinder (03).

15. The apparatus according to claim 14, characterized in that in the pressure-on position depending on the electrical power (L06) of the drive motor (06) a peripheral speed (u03) of the impression cylinder (03) relative to a peripheral speed (u04) of the transfer cylinder ( 04) is changeable.

16. The apparatus according to claim 13 or 14, characterized in that the first drive motor (06) with respect to an amount falling electrical power (L06) is adjustable.

17. The apparatus according to claim 16, characterized in that the first drive motor (06) with respect to an amount according to the minimum power (L06) is adjustable.

18. The apparatus according to claim 16, characterized in that at the same time a relative deviation (ΔU) in the peripheral speeds (u03; 04) of the cylinders (03; 04) or the speeds (n06; n07) of the drive motors (06; 07) is within a permissible interval.

19. The apparatus according to claim 16, characterized in that the interval for the permissible relative deviation (ΔU) in the peripheral speeds (u03; u04) by a first limit value (ΔU1) to smaller peripheral speeds (u03) of the impression cylinder (03) compared to Transfer cylinder (04) and by a second limit value (ΔU2) TO greater peripheral speeds (u03) of the impression cylinder (03) compared to the transfer cylinder (04) is formed.

20. The apparatus according to claim 19, characterized in that the first limit value (ΔU1) is formed by a maximum deviation (ΔU) of - 0.05 to - 0.01%, in particular approximately - 0.02%.

21. The apparatus according to claim 19, characterized in that the second limit value (ΔU2) is formed by a maximum deviation (ΔU) of + 0.05 to + 0.01%, in particular approximately + 0.02%.

22. Device for driving a printing unit with at least one satellite cylinder (03) and at least two transfer cylinders (04), which can be set together on a satellite cylinder (03) and each form a printing point (01), the satellite cylinder (03) using a first drive motor (06) can be driven mechanically independently of the transfer cylinders (04), characterized in that in the print-on position at least one of the satellite cylinders (03) contributes to an electrical power (L06) decrease in the drive motor (06) variable peripheral speed (u03), and one or more of the transfer cylinders (04) with respect to a predeterminable peripheral speed (u04-should; u) are adjustable.

3. Apparatus according to claim 22, characterized in that a relative deviation (ΔU) in the peripheral speeds (u03; u04) a first limit value (ΔU1), in particular with approximately (ΔU1) approximately - 0.02%, to smaller peripheral speeds (u03) of the impression cylinder (03) in comparison to the transfer cylinder (04) and does not fall below a second limit value (Δu2), in particular with (ΔU2) approx. + 0.02%, for greater peripheral speeds (u03) of the impression cylinder (03) compared to the transfer cylinder (04).