DE4344896C5 - Drive for cylinder of a web-fed rotary printing machine - Google Patents

Abstract

Drive for cylinder of a web-fed rotary printing machine with
a) a color-transmitting first cylinder pair, comprising a first blanket cylinder and a first plate cylinder, which are mechanically coupled together for common drive during printing by a first motor,
b) a color-transmitting second cylinder pair comprising a second blanket cylinder and a second plate cylinder mechanically coupled together for common drive during printing by another, second motor;
c) a color transmitting third cylinder pair comprising a third blanket cylinder and a third plate cylinder mechanically coupled together for common drive during printing by yet another, third motor,
d) a color-transmitting fourth cylinder pair, comprising a fourth blanket cylinder and a fourth plate cylinder, which are mechanically coupled together for common drive during printing by a further, fourth motor,
e) per plate cylinder at least one respective plate cylinder associated inking roller and
f) one controller each for the engines,
g) where the ...

Description

The present invention relates to a drive of cylinders of a web-fed rotary printing press according to the preamble of claim 1, as known from JP-A 63-236651 is known.

Conventional rotary printing machines become from a main drive over a mechanical longitudinal shaft, also royal wave called, driven A disadvantage of these printing machines is the mechanical effort to be compensated during the Run occurring torsion of the longitudinal shaft. As a result, a mechanical circumferential register adjustment of pressure points the printing press during of the run necessary.

At one of the DE 34 09 194 A1 Although this motor can indeed be directly connected to the drive gear of a single of the printing units, however, the drive gears of the other printing units are mechanically coupled only to the drive gear connected to the motor.

It also tries the mechanical longitudinal shaft between the individual printing units by an electric longitudinal shaft to be replaced Each printing unit has a separate electric drive. To the high mechanical effort, because of the complexity of the individual printing units with several pressure points is still to operate, comes in This case still a high technical control effort added because of Synchronous operation of the individually driven printing units with each other must also be ensured.

To avoid the problems mentioned in the DE 4138 479 A1 proposed to drive the cylinders of the printing press by a respective electric motor.

From the DE 42 14 394 A1 is a control system for such a printing machine, each with individually driven cylinders known Here, the individual drives of the cylinder and the drive controller can be combined to groups of pressure groups arbitrarily. The groups of printing groups are assigned to folders from which they obtain their position reference. The proposed control system consists essentially of a fast BUS system for the individual drives and the drive controllers of a print group and a higher-level control system for the management of print group groups.

Although the concept of the individually driven cylinder pursued in these two publications allows a high versatility of use, at the same time it requires a very high level of drive motors and, like the DE 42 14 394 A1 shows a high control effort for this large number of individual drives. In addition, a variety of motors must be used. If only a few engine sizes are used, otherwise oversized motors would otherwise be used for different applications. Both drive the price of such a printing press.

One from the aforementioned JP-A 63-236651 known printing machine has printing units that are driven individually by their own drive motors. The motors each drive on the plate cylinders of the printing units, and the plate cylinders are driven on the printing cylinders via gear coupling. The engines sit directly on the shafts of the plate cylinder.

The present invention has it set itself the task of a highly flexible, yet to create economic rotary printing press

This task is governed by the subject matter of Claim 1 solved.

The dependent claims are on appropriate and not smooth course embodiments of the subject matter of claim 1.

According to the invention form blanket cylinder and plate cylinder of a rotary printing machine in pairs one Cylinder group, in each case a blanket cylinder and a plate cylinder mechanically coupled together and together by a own drive motor per cylinder group to be driven.

Through this groupwise summary the two cylinders and their equipment me with a single drive for at least A pair of cylinders will significantly increase the number of drive motors required reduced; at least halved compared to the single drive concepts The mechanical coupling of these two each other by printing technology Cylinder, preferably a gear coupling with straight or helical gears offers across from the concept of each individually driven cylinder significant Price advantages. In terms of versatility are compared to the Single drive concept to make any significant trade-offs. So can both the Umfangsregister- and the side register adjustment each blanket cylinder individually and to any further arbitrary Blanket cylinder, if necessary, be made coordinated. By the cylinder groups according to the invention with, respectively own drive motors can in a rotary printing machine in technical and economic Optimal pressure points are formed. As bruises In this context, the cylinders are understood, respectively, between where a paper web to be printed passes and one or both sides Accordingly, belong to an inventively formed Pressure point in each case a blanket cylinder and a corresponding Gegendruckrylinder.

According to the invention, the blanket cylinder is driven, which in turn aborts the mechanical coupling on the plate cylinder The solution has the advantage that the cylinder, the last Lich with a paper web to be printed directly comes into contact, not only on a possibly afflicted with game transfer member must be driven.

The counterpressure cylinder is another blanket cylinder for bilateral Pressure.

The output of a drive motor to the respective cylinder group is preferably carried out by means of a toothed belt. Opposite in the DE 41 38 479 A1 and the JP-A 63-236651 proposed solutions of the seated on the drive shaft of the driven cylinder rotor of the electric motor such a timing belt has a high elasticity For the control concept of driving a cylinder group, however, given by the use of a toothed belt possibility of high damping of existing from a drive motor and the driven cylinders mechanical Systems of great value, as will be explained. Compared to a gear drive between the drive motor and the driven cylinder of a cylinder group, as he may also apply, a toothed belt has the advantage of a backlash-free run and a not absolutely fixed gear ratio.

In contrast, for the mechanical coupling gears are provided between the cylinders within a cylinder group, although other transmission links It is also conceivable that the meshing gears can be straightforward or helical teeth his. With helical teeth gears is moved longitudinally to the Seitenregisterversteliung the blanket cylinder, while his Drive and / or driven gears stationary according to the invention stay. Otherwise it would be with the Seitenregister- also a circumferential register adjustment required. When sprocket wheels are used, the blanket cylinder becomes along with its fixed gear or its gears easy moved longitudinally.

The ink roller or ink rollers an inking unit, which is assigned to a cylinder group can or can According to the invention mechanically be coupled to this cylinder group, so that the ink roller or the ink rollers be driven by the drive motor of this cylinder group. By this solution the regulatory technical effort can be kept low. on the other hand is the mechanical coupling of the inking unit in the sense of with the Invention pursued modular principle not quite as ideal as the stronger preferred propulsion for the roller or rollers of the inking unit. After that, each inking unit has its own drive motor for his paint rollers. Such a drive motor also preferably drives over one Backlash-free timing belt with high damping and possibly a Reduction gear scrape the paint roller or in case of multiple Ink rollers that the plate cylinder of the corresponding cylinder group the next lying ink roller on. Here is the peripheral speed of this Ink roller advantageously adjustable, especially with negative Slip over the plate cylinder, so that the Peripheral speed of the ink roller slightly lower than that of corresponding plate cylinder is

The drive motors of the cylinder group pen of a cylinder unit are position controlled. Preferred is a so-called ideal position control, d. H. a delay-free position control with a following error connection. On these, for technical reasons, desired, However, complex type of position control can certainly be dispensed with A simple attitude control is also a preferred, in particular cheaper, embodiment of the Invention.

The regulation of the situation and / or the Speed of the cylinder to be controlled a cylinder group or, a Roller of an inking unit according to the invention by means of a controller for the drive motor by the target / actual comparison of the output signals of a reference value encoder and an actual value encoder, this actual value encoder, the position and / or the speed of the cylinder or the roller detected in contrast to the known Regulations with rotary printing machines thus becomes a loader for the scheme used. In contrast, was previously a mechanical encoder in the printing press on the Motor side for detecting the engine speed or the rotor angle position the engine for the target / actual comparison of the engine control used in this conventional Control comes up great Inertia conditions from the load to the engine quickly to the dynamic limits. Will the Regulator unstable, especially the engine starts to swing while the Load remains relatively calm.

In control engineering are for so-called dual mass oscillator Differential circuits, Regelkaskeden and active filters known but all a big one require technical control effort. For the above Load / engine systems, d. H. the self-propelled cylinder groups, has it surprisingly as completely sufficiently proved, the regulation essentially by means of a Actual value to lead the one by one at the load, namely on one of the cylinders of a cylinder group, attached actual value encoder has been determined This actual value distance angular position and / or speed of the cylinder concerned - is enough To achieve a high level of dynamics and control quality even from alone.

By the actual value to be controlled according to the invention is taken off the load, what is measured, what exactly has to run, namely the load, not the motor, is also measured. The existing of the drive motor, a coupling and the load mechanical replacement system is to be regarded as a low-pass filter. In this type of control, the low-pass filter of the motor-coupling-load-distance system is exploited to shocks and vibrations in the controlled system arise to filter. Such shocks and vibrations are thus returned to a reduced extent in the controller. The risk of upswing is thereby reduced The dynamics of the control and thus also the control performance can be significantly increased compared to the described conventional control with identical coupling.

The figuratively speaking from the engine side to Load side swept actual value encoder is the main controlled variable for the controller of the engine, d. H. the engine is from the load side through their Actual value led According to a particularly preferred embodiment of the invention No mechanical actual value encoder for detecting the position or the speed of the engine as part of the regulation of the engine needed. A possibly integrated in the engine actual value detection can be advantageous for the pure drive monitoring, if necessary for a motor emergency shutdown can be used.

The actual value encoder for the control is according to the invention on the torque-free shaft end of the driven cylinder of a cylinder group or the driven Roller of an inking unit attached.

Particularly advantageous are electric asynchronous motors as the drive motors used So far became an asynchronous motor used only when using a large motor a small load was to drive. For the present case in which a drive motor is a cylinder group or also drives the rollers of an inking unit, in which therefore the driven Load a comparatively high mass moment of inertia compared to the Drive motor has, the use of asynchronous motors is not known for the purposes of the control according to the invention with a loader instead of a motor encoder are asynchronous motors particularly suitable opposite the for the DC motors used in the respective applications Asynchronous motors have a higher Field stiffness so that you Use the dynamics and control quality of the system to be controlled improves the use of other engine types, For example, DC motors, but is not excluded in principle.

The stability of the scheme is determined by the preferred use of a backlash-free toothed belt with high damping than Coupling between engine and load additionally improved

The drive motor may be in the in The speech of two mass oscillators even disregarded as a low-pass filter acting load is insensitive to the vibrations of the other hand essential smaller engine. On the other hand the repercussions neglected by the load on the drive motor.

With the concept of pairwise summary from blanket and plate cylinders to cylinder groups becomes one Maximum flexibility, while the price for such an organized printing press with respect to a printing press with individually driven cylinders can be lowered considerably for one out such cylinder groups composite printing machine drive motors in only two, at most three power classes needed, while at directly and individually driven cylinders basically each separately Motors for Cylinders of various lengths and diameters required are. By means of the invention used Cog belt drives can possibly within wide limits fluctuating mass moment of inertia between the load and the engine by appropriate choice of translation be caught and matched. The reduction of Number of drive motors along with the advantage that motors only have to be provided in a few performance classes offers already significant price advantages. This advantage is due to the use the invention simple Control, which is also flexibly adaptable to changing inertia conditions, even stronger Here are the advantages achieved by the invention with increasing Printing machines, d. H. with increasing number of printing units and Pressure points per machine, more and more effective. In particular the invention finds use in the construction of offset rotary printing presses; but it is not limited to this type of machine.

Preferred embodiments of the present invention Invention will be explained below with reference to the figures Further features and advantages of the invention are disclosed demonstrate:

1 a pressure point with two cylinder groups;

2 a cylinder group with an associated self-propelled inking roller;

3 a control of the drive for a cylinder group according to the prior art;

4 a control for driving a cylinder group according to the invention;

5 a comparison of the dynamic behavior of a conventional control and a control after the ending in dependence on the mass moment of inertia of the engine and load;

6 a comparison of the dynamic behavior of a conventional control and regulation according to the invention as a function of the torsional rigidity of the coupling between the engine and the load; and

7 a control diagram of the regulator.

At an in 1 The printing point shown becomes a paper web to be printed 1 between the two opposite blanket cylinders 2 two cylinder groups 10 passed through the two cylinder groups 10 are each through the blanket cylinder 2 and an associated plate cylinder 3 formed for the ge common drive are mechanically coupled together. The mechanical coupling is schematically represented by a connecting line between the centers of the two cylinders 2 and 3 indicated in the exemplary embodiment 1 are each the blanket cylinder 2 each cylinder group 10 by a three-phase motor 5 driven The configuration according to the 1 , in each case only one blanket cylinder 2 and a plate cylinder 3 by a mechanical coupling to a cylinder group 10 are characterized by their simple design and the highest possible degree of freedom in configuration in the formation of pressure points or pressure point groups.

In 2 is the interaction of a blanket / plate cylinder pair 2 . 3 existing cylinder group 10 with a paint roller 7 represented here has the ink roller 7 via its own drive by a motor 5 that's the engine 5 for the cylinder group 10 may be identical, but not necessarily. The motor 5 for the ink roller 7 drives over a toothed belt 15 and a gear pair 16 . 17 , wherein the tooth rad 17 on the shaft of the ink roller 7 sits, the paint roller 7 on The different moments of inertia of the motor 5 and the ink roller 7 By suitable choice of the gear ratios when driven through the timing belt 15 and the gear pair 16 . 17 defused.

The peripheral speed of the ink roller 7 is adjustable with a slight negative slip against the plate cylinder 3 , This can be counteracted the risk that by a gear pair 12 . 13 formed mechanical coupling between the blanket cylinder 2 and the plate cylinder 3 is lifted from the tooth mesh.

The drive of the cylinder group 10 done by the engine 5 over the timing belt 11 on the blanket cylinder 2 , The mechanical coupling between the blanket cylinder 2 and the plate cylinder 3 the same cylinder group 10 form the two gears 12 and 13 , To defuse a high ratio of the mass moments of inertia of load and drive, namely cylinder group 10 and engine 5 , the speed of the engine 5 over the timing belt 11 appropriately stocked This timing belt 11 is the elastic coupling between the engine 5 and the driven cylinder group 10 , Compared with a gear coupling is with the timing belt 11 a very high damping of the motor / load system 5 . 10 achieved The same applies in principle to the drive of the inking roller 7 and its coupling member, the timing belt 15 , Furthermore, the choice of a toothed belt drive because of the infinitely variable ratio creates a great deal of constructive freedom The motors 5 for the cylinder group 10 or the ink roller 7 are each three-phase motors with a high field stiffness. Again, the modular principle of Bilding of cylinder groups or groups of rollers with toothed belt coupling to the drive motor comes into play, since with less engine performance sizes, the entire Variation variety of cylinder or roller lengths and diameters can be equipped with correspondingly different mass moments of inertia.

The two gears 12 and 13 showing the mechanical coupling between the blanket cylinder 2 and the plate cylinder 3 may be helical or spur gears. In the case of helical gears is the blanket cylinder 2 in the Seitenregisterverstellung longitudinally displaced while the gear 12 and the corresponding gear for the timing belt 11 remain stationary, d. h these two gears are on the cylinder shaft 14 longitudinally displaceable In the case of a straight toothing of the two gears 12 and 13 sit the gear 12 and the gear for the timing belt 11 stuck on the shaft 14 and be together with the blanket cylinder 2 and the engine 5 for the cylinder group 10 moved longitudinally together.

In contrast to the regulations known in rotary printing machine construction, the motor / load system 5 . 10 guided by an actual value, the one of the load side, namely at the torque-free end of the shaft 14 the blanket cylinder 2 attached mechanical loader 21 is produced. The same type of regulation, namely me one on the load-free shaft end of the ink roller 7 attached loader 27 is used to control the speed of this ink roller 7 selected.

A known in printing machine construction control is in 3 shown schematically The control of the engine 5 that has a flexible coupling 24 a burden 25 drives, by means of a regulator 23 , Weight 25 is a heavy roll or a heavy cylinder or a corresponding roll or cylinder system whose mass moment of inertia is typically more than five times that of the engine 5 Nevertheless, the regulation of this motor / load system should be optimized in terms of performance and with sufficiently high control quality for the speed or the angular position and the speed of the load 25 It should be regulated to the coupling 24 The motor and load requirements are not too high in terms of their torsional rigidity and backlash.

In the known systems, such as one in 3 is a mechanical actual value encoder 21 for generating a position or speed and the position of the rotor of the motor 5 characteristic electrical signal attached to this rotor The load 25 is with the coupling 24 , which has an elasticity and possibly a certain clearance, attached to the motor shaft end The coupling and the load are outside the actual control loop. However, you can influence this by means of the acceleration torques acting on the motor shaft.

This system encounters large crowds The inertia of the load to the engine quickly approaches its dynamic limits. If the control unit becomes unstable, the engine will vibrate while the load remains relatively quiet.

4 shows, however, a scheme in which, as in 2 already described, the reference variable for the regulation of a donor 21 is generated at the load 25 and not on the engine 5 is attached This actual value encoder 21 is at the free shaft end of the load, in the embodiment at the free shaft end of the blanket cylinder 2 a cylinder group 10 , attached This actual value encoder 21 is therefore hereinafter referred to as loader The coupling 24 is due to the already described timing belt 11 formed against me a direct coupling or a gear coupling high elasticity but also high damping In addition, this coupling 24 with a toothed belt play free.

The needed for the control, from the loader 21 generated actual value, the angular position of the blanket cylinder 2 or whose speed and its angular position represents is on the controller 23 recycled. A computer-generated setpoint from the setpoint generator 22 is compared with this actual value and to form a control signal for the motor 5 used.

In this regulation are the coupling 24 and the load 2S within the actual control loop. The load and the coupling 24 Form a low-pass filter for the resulting in the control system shocks and vibrations, which thus only in a reduced degree in the controller 23 and therefore can not lead to unwanted suggestions of the regulation. As a result, the dynamics and the quality of control compared to conventional systems is substantially increased even with otherwise the same coupling The system, consisting of controller, engine, clutch and cylinder, is already much more attenuated in itself. Resonance peaks therefore do not occur to the same extent. The controller can therefore be set faster without leaving the stable working area.

One on the engine if necessary 5 attached, according to the embodiment 4 Actual value detection shown can be used for additional monitoring of the engine 5 , for example, at a desired emergency shutdown of the engine 5 be used.

In the diagrams of 5 and 6 is the dynamic behavior of the two regulations according to the 3 and 4 compared. As a measure of the dynamics of the control, the reciprocal value of the reset time T _{i of} the drive is selected. In 5 the dynamics is shown as a function of the mass inertia ratio of load to motor with identical coupling and identical phase reserve 4 with the actual value detection on the load, especially with larger mass inertia ratios of the actual value detection on the motor according to 4 is clearly superior.

In 7 is the dynamics as a function of the torsional rigidity of the coupling 24 imaged at constant mass inertia ratio and identical phase reserve. This shows the regulation 4 especially at low torsional stiffness of the coupling compared to the conventional control accordingly 3 think.

7 shows the control diagram of the controller 23 , The setpoint and the actual value, in the exemplary embodiment, the desired or actual center position of a blanket cylinder 2 , are used to form the difference setpoint actual value a first differential amplifier 31 fed. The difference D ₁ formed there is a first proportional amplifier 34 fed and proportional amplified signal K ₁ XD ₁ to a second differential amplifier 35 given. In parallel, the setpoint and the actual value are each a differentiator 32 or supplied 33, differentiated and the corresponding output signals Ṡ _s and Ṡ _i to the second differential amplifier 35 The sum formed there k ₁ D ₁ + Ṡ _s - Ṡ _i ; is in a second proportional amplifier 36 reinforced and via an integrator 37 a current regulator for the motor 5 supplied

Claims (9)

A cylinder drive for a web-fed rotary printing press comprising: a) a first cylinder color transfer cylinder comprising a first blanket cylinder and a first plate cylinder mechanically coupled to each other during printing by a first motor, b) a second cylinder color transfer cylinder pair comprising a second blanket cylinder and a second plate cylinder mechanically coupled together for common drive during printing by another, second motor; c) a color transmitting third cylinder pair comprising a third blanket cylinder and a third plate cylinder adapted for co-driving during printing through yet another, third engine are mechanically coupled to each other, d) a color-transmitting fourth pair of cylinders, comprising a fourth blanket cylinder and a fourth plate cylinder, the common drive during printing by a wide e) per plate cylinder at least one ink roller assigned to the plate cylinder and f) one each for the motors, g) the first blanket cylinder having the third blanket cylinder having a first printing nip and the second blanket cylinder being the fourth Blanket cylinder form another, second nip for the web characterized in that h) the regulators via the motors ( 5 ) the circumferential register adjustment of the blanket cylinder ( 2 ), i) the first engine ( 5 ) via a transmission ( 11 ) the first blanket cylinder ( 2 ), the second engine ( 5 ) via another transmission ( 11 ) the second blanket cylinder ( 2 ), the third engine ( 5 ) about yet another transmission ( 11 ) the third blanket cylinder ( 2 ) and the fourth engine ( 5 ) via another gear ( 11 ) the fourth blanket cylinder ( 2 ) j) each of the gears ( 11 ) each by means of a toothed belt or each of the transmission ( 11 ) are each formed by means of a gear coupling, k) and that in each of the pairs of cylinders ( 10 ) from the blanket cylinder ( 2 ) on the plate cylinder ( 3 ) of the respective cylinder pair ( 10 ) is driven off. Drive according to one of the preceding claims, characterized in that the mechanical coupling within the pairs of cylinders ( 10 ) by gears ( 12 . 13 ) is formed. Drive according to one of the preceding claims, characterized in that at least one inking roller ( 7 ) of an inking unit which corresponds to a pair of cylinders ( 10 ) is assigned mechanically with this pair of cylinders ( 10 ) is coupled. Drive according to claim 1 or 2, characterized in that for driving at least one inking roller ( 7 ) of an inking unit which corresponds to a pair of cylinders ( 10 ), a separate motor ( 5 ) is provided. Drive according to claim 4, characterized in that the peripheral speed of a against the plate cylinder ( 3 ) of a cylinder pair ( 10 ) rolling roller ( 7 ) with a negative slip relative to the plate cylinder ( 3 ) is adjustable. Drive according to one of the preceding claims, characterized in that at least the drive motors ( 5 ) on the same pressure side of the paper web ( 1 ) working cylinder pairs ( 10 ) a cylinder unit ( 20 ) are positionally controlled relative to one another. Drive according to one of the preceding claims, characterized in that the controller ( 23 ) the engine ( 5 ) of the first blanket cylinder ( 2 ) based on a predetermined angle of rotation - setpoint for the first blanket cylinder ( 2 ) and an angular position actual value, which is measured by an encoder ( 21 ) for generating the rotational angle position of the first blanket cylinder ( 2 ) is recorded. Drive according to claim 7, characterized in that the encoder ( 21 ) at the torque-free shaft end of the cylinder ( 2 ) is attached. Drive according to one of the preceding claims, characterized in that the motors ( 5 ) are formed by electric asynchronous motors.