EP1815979A2 - Method for active compensation of vibrations in a print substrate processing machine and print substrate processing machine - Google Patents

Abstract

The method involves measuring a signal containing an uncompensated oscillation of a machine (1). A measure of a ratio between an amplitude of the uncompensated oscillation and an amplitude of a counter torque necessary for complete compensation is compared with a threshold value. The counter torque to be introduced is determined on the basis of two different functional relationships with the uncompensated oscillation if the measure is greater/smaller than the threshold value, and the counter torque is introduced into the machine. An independent claim is also included for a machine for processing printing materials, comprising a regulating device.

Description

The invention relates to a method for active compensation of vibrations in a substrate-processing machine, in particular in a printing press, in which at least one signal which contains a vibration of the machine or a part of the machine is measured and at least one counter-torque for reducing the vibration in the machine is introduced. Furthermore, the invention relates to a substrate-processing machine with a control device for active compensation of vibrations in the printing material processing machine.

In substrates processing machines (also referred to as printing material processing machines), in particular printing machines, occurring vibrations, in particular non-integer order with respect to the operating frequency of the machine, undesirable and, since they have an impact on the quality of the manufactured products to be combated. Undesirable oscillations are often actively compensated by introducing a suitable counter-moment into the substrate-processing machine to counteract the measured vibration.

From the document DE 101 49 525 A1 or the document US 6,796,183 B2 as well as from the document US 5,596,931 For example, active vibration compensations are known for substrate-processing machines in which amplitudes and phases of discrete oscillations of different frequency are measured and processed in a control loop in order to determine adequate counter-moments for the compensation. From the document DE 102 17 707 A1 or the document US 2003/0230205 A1 shows that an active on a drive control for a substrate processing machine, an active vibration compensation can be switched, wherein the calculation of the compensation vibration by means of a filter with their frequency parameters.

To compensate for periodic disturbances is further example, from the document DE 197 40 153 A1 as well as from the document DE 103 55 122 A1 It is known to provide an observer or a periodic compensation controller in a drive control loop in order to obtain input values for an actuator or a desired torque.

In practice in printing material processing machines, in particular printing machines, it has been shown that for certain parameters, such as the excitation frequency for a counter-torque to be introduced, or combinations of parameters for certain compensation objectives, such as the reduction of a cylinder oscillation or oscillation of a cylinder combination, with a certain oscillation frequency Use of active vibration compensation leads to an unexpected increase or increase of vibrations at some measuring points in the substrate-processing machine.

In particular, in an unfavorable position of the point at which the counter-moment is introduced into the substrate processing machine, in particular in the printing press, with respect to the waveform of a disturbance with a certain frequency, as well as with respect to the drive positions (motor positions) and / or measuring positions (Encoder positions) Although the vibration to be compensated can be regulated to zero for a monitored compensation target, the vibration amplitude at other measuring points in the machine can increase due to the active vibration compensation. In an unfavorable case, this means that the active vibration compensation can degrade the processing quality, in particular the print quality. Even with a skilful selection of possible points for introducing a counter-torque, drive positions and measuring positions, the problem is not completely avoidable. Often a free selection of the positions and / or the number of drive positions and measuring positions is not possible anyway, since many boundary conditions, such as an upper limit for the possible gear train load, are complied with.

Object of the present invention is to reduce unwanted vibration gains in an active vibration compensation of a printing material processing machine or even avoid.

This object is achieved by a method for the active compensation of vibrations in a substrate-processing machine having the features of claim 1. Advantageous developments of the invention are characterized in the dependent claims.

In the method according to the invention for the active compensation of vibrations (also referred to as active vibration damping, vibration reduction or vibration reduction) in a printing material processing machine, in particular in a printing machine, at least one signal which is a vibration of the machine or of a part of the machine, especially at a first Frequency, contains, measured (also detected or recorded). At least one counter-torque (also referred to as compensation torque) for reducing the vibration, in particular at the first frequency, is introduced into the machine. At least one measure of the ratio between the amplitude of the uncompensated oscillation and the amplitude of the counter-torque necessary for complete compensation (also referred to as the transmission behavior of the process or as the sensitivity of the machine or as the response of the machine) is compared with a threshold value. The counter-torque, in particular the value and / or the phase of the counter-torque to be introduced, is determined in a first functional relationship with the vibration, in particular its amplitude and phase, if the dimension is greater than the threshold value, and the counter-torque to be introduced in a second functional relationship with the vibration, which is different from the first functional relationship, determines if the measure is smaller than the threshold value. In other words, above the threshold value, the compensation takes place with an acting counter-torque in a first operating mode and below the threshold value in a second operating mode. The calculation, determination or determination of the acting counter-torque takes place above the threshold in a first way (after a first rule) and below the threshold in a second way (after a second rule).

With the method according to the invention can be achieved in an advantageous manner as a compensation target in particular a complete vibration compensation, that is, a compensation to below a desired minimum limit. In an inventive way unfavorable parameters or parameter combinations can be countered by changing the parameters of the active vibration compensation, so that a less strong, only a sufficiently small or even no unwanted excitation results. Advantageously unfavorable constellations can be avoided in which vibrations of the machine are amplified by an active compensation. There is only the least possible interference with the machine dynamics. It is clear to the person skilled in the art that the counter-moment to be introduced and acting has a time course, a signal course. In particular, it may have a frequency spectrum around a first frequency or main frequency. The value or amount of the counter-torque to be introduced may in particular be the maximum or absolute value of the amplitude. The phase position of the counter-torque can in particular counteract the phase position of the oscillation to be compensated.

Advantageously, can be achieved with the inventive method that when changing an operating parameter of the printing machine processing machine, for example, the machine speed, in particular the printing press, for example, their printing speed, dependent on this operating parameters excitation frequencies are in a frequency interval in which the measure of the ratio between the amplitude of the uncompensated oscillation and the amplitude of the counter-torque necessary for complete compensation is above the threshold value, the value of the counter-torque to be introduced is determined in the first functional relationship with the magnitude of the oscillation, while otherwise determining the value of the counter-torque in the second functional relationship. In a monotonous change in the operating parameter of the printing material processing machine, for example, a monotonous increase in the printing speed of the printing press, a successive switching or switching between the introduction of the Gegenmoments according to the first functional relationship and the introduction according to the second functional relationship result.

The compensation target may be the regulation of a vibration of the entire machine or of a vibration of a part of the machine, in particular of a single component of the machine, essentially to zero, preferably exactly to zero, in particular within the limits of tolerance limits. The oscillation to be compensated may in particular be a rotational oscillation. The measure of the ratio between the amplitude of the uncompensated oscillation and the amplitude of the counter-torque necessary for complete compensation can be the magnitude of the oscillation, the absolute magnitude of the amplitude of the oscillation, or the amplitude of the transfer function between the counter-momentum introduced by an actuator and the oscillation to be compensated be. The counter-torque may have the first frequency or a second frequency different from the first one. The counter-torque can be switched to a drive torque of the machine, in particular the main drive of the machine. The counter-moment can have a fixed frequency. If the measure is equal to the threshold value, it can be determined in the method according to the invention, depending on the embodiment, that the counter-torque to be introduced is determined either in the first functional relationship with the vibration or in the second functional relationship.

In a preferred embodiment of the method according to the invention for the active compensation of vibrations, the counter-torque to be introduced in the second functional relationship is substantially zero or close to zero, preferably exactly zero. In other words, below the threshold, that is, according to a fixed criterion, in this embodiment, the active vibration compensation is turned off while being turned on above the threshold. The active vibration compensation works only when it is actually needed.

It is furthermore advantageous if, in the method according to the invention, the amplitude of the transfer function (also referred to as frequency response) serves as a measure between the counter-torque and the oscillation and it is compared as to whether the transfer function exceeds the threshold at least one frequency, so the transfer function exceeds a specified or selected amount. In particular, the exceeding of the amount by the transfer function can form a criterion for the switching on and off of the active vibration compensation. In other words, the active compensation can be turned on only when the amplitude of the transfer function at the current oscillation frequency (the oscillation to be compensated) exceeds a predetermined threshold. The advantageous criterion may be the transfer function between the engine torque and the compensation target. It can be advantageously avoided or reduced from this manner that an undesired increase or increase in vibrations takes place at some of the measuring points in the printing machine when the value of the transfer function between the counter-torque, in particular the drive torque, and the compensation target is small.

The active vibration compensation can be switched on in concrete embodiments of the method according to the invention only when the monitored vibration order of the printing material processing machine, in particular printing machine, at the current operating speed, in particular printing speed, in the vicinity of a resonant frequency. For the printing material processing machine, the resonance frequencies and the threshold values for the comparison according to the invention are determined with the measure for the ratio between the amplitude of the uncompensated oscillation and the amplitude of the counter-torque required for complete compensation as a function of the operating speed.

Furthermore or alternatively, it can be provided in the method according to the invention for the active compensation of vibrations that the transfer function between the counter-torque and the oscillation is measured for initialization. In this way, the necessary threshold value can be determined automatically with little programming or care effort in the substrate-processing machine, so that the ranges for the first operating mode and the second operating mode are determined.

In specific embodiments of the method according to the invention, the point of measurement of the vibration of the machine or of a part of the machine at the first frequency and the point of introduction of the counter-moment to reduce the vibration can not coincide. In other words, measuring devices, such as sensors, encoders, encoders or the like, can be positioned at measuring points, while the counter-torque is transmitted via an actuator, such as a drive or motor, at a different location on the machine.

It is particularly preferred if, in one embodiment of the method according to the invention, the printing material-processing machine is driven or controlled to an operating frequency. In other words, the method of compensating for vibrations eliminates undesirable disturbances in a control or regulation of the printing material processing machine, in particular in the control or regulation of the main drive of the printing material processing machine.

The method according to the invention can be embodied such that the amplitude and the phase of the oscillation are determined from the measurement. In particular, an embodiment of the method according to the invention may also have features or combinations of features of the active vibration compensation described in the document DE 101 49 525 A1 or in the document US 6,796,183 B2 have been made available to the public. The disclosure of the document DE 101 49 525 A1 or the document US 6,796,183 B2 is incorporated by explicit reference into this disclosure.

The inventive method may further or alternatively be designed such that the at least one counter-torque by means of a filter which determines a transfer function with a frequency parameter which corresponds to the frequency of the oscillation to be compensated, is determined. In particular, an embodiment of the method according to the invention may also have features or combinations of features of the active vibration compensation described in the document DE 102 17 707 A1 or in the document US 2003/0230205 A1 open to the public have been made. The disclosure of the document DE 102 17 707 A1 or the document US 2003/0230205 A1 is incorporated by explicit reference into this disclosure.

In the method according to the invention, the oscillation to be compensated may be a vibration of a machine shaft or a signal value difference of two or more than two machine shafts or an eigenmode of the printing material processing machine or an eigenmode of a part of the printing material processing machine.

Furthermore, or alternatively, the frequency of the oscillation may be a non-integer multiple of an operating frequency of the substrate-processing machine.

In specific embodiments of the method according to the invention, it is particularly preferred if the method is used for a plurality of oscillations of different frequency, in particular simultaneously. In particular, a plurality of vibration eigenmodes of the printing material processing machine can be compensated.

In connection with the method according to the invention is also a printing material processing machine, in particular a printing press, with a control device for the active compensation of vibrations in the printing material processing machine. According to the invention, the control device of the substrate-processing machine for carrying out a method with features or combinations of features according to this representation is pronounced and is, if the measure of the ratio between the amplitude of the uncompensated oscillation and the amplitude of the necessary for complete compensation counter-torque for the sensitivity of the machine greater is operable in a first mode, and operable in a second mode when the measure of the ratio between the amplitude of the uncompensated oscillation and the amplitude of the counteracting required for complete compensation for the sensitivity of the machine is less than the threshold.

The substrate-processing machine according to the present invention may be, in particular, a printing machine (for example, an offset printing machine or a multi-color printing machine or a label printing machine or a label printing machine), a printing form setter (for example, an offset printing plate external drum platesetter) or a printing finishing machine (for example, a punching machine or a folding machine or a saddle stitcher).

The method according to the invention is particularly preferably used in printing presses with a high number of printing units, that is to say with eight or more printing units, in particular offset printing units.

Figur 1

ein Schema einer Ausführungsform einer erfindungsgemäßen Bedruckstoff verarbeitenden Maschine mit einer Regelungseinrichtung ausgeprägt zur Durchführung des erfindungsgemäßen Verfahrens,

Figur 2

ein Schema einer alternativen Ausführungsform einer erfindungsgemäßen Bedruckstoff verarbeitenden Maschine mit einer Regelungseinrichtung ausgeprägt zur Durchführung des erfindungsgemäßen Verfahrens, und

Figur 3

eine graphische Darstellung der Bedeutung des erfindungsgemäßen Schwellwerts für das Ein- und Ausschalten der aktiven Schwingungskompensation in einer bevorzugten Ausführungsform des erfindungsgemäßen Verfahrens.

Further advantages and advantageous embodiments and developments of the invention will be described with reference to the following figures and their descriptions. It shows in detail:

FIG. 1

a diagram of an embodiment of a printing material processing machine according to the invention with a control device pronounced for carrying out the method according to the invention,

FIG. 2

a diagram of an alternative embodiment of a printing material processing machine according to the invention with a control device pronounced for performing the method according to the invention, and

FIG. 3

a graphical representation of the importance of the threshold value according to the invention for switching on and off the active vibration compensation in a preferred embodiment of the method according to the invention.

Before looking at features and details of advantageous embodiments of printing material processing machines according to the invention with reference to the illustration in Figures 1 and 2, the sequence of provision and execution of a preferred exemplary embodiment of the method according to the invention is described at this point.

For the active compensation of a vibration sensors for measuring the vibration amplitude and a motor for applying the compensation torque or counter-torque are needed. To apply the compensation moments of the already existing main drive of the printing material processing machine can be used. It has been found that it makes sense to use two encoders as sensors, one of the encoders being at the beginning of the machine and the other at the end of the machine. In this case, the already existing machine tachometer can be used as an encoder or sensor, so that only an additional encoder is needed.

Simulation calculations can be used to find motor positions that are particularly advantageous for active vibration compensation. However, there are various restrictions, as for the position of the main drive and the machine tacho further criteria are observed, so that usually not the most favorable for the active vibration compensation configuration is feasible. For example, the motor may not be located in a node for applying the compensation moments. The vibration node is often located approximately in the middle of the machine. At the same time the drive position is selected in printing machines such that the Räderzugbelastung and the static pressure offset are minimized. For a specific machine design or a specific machine model, the engine positions are therefore determined as a compromise between the requirements for active vibration compensation and the other restrictions.

The compensation target is the amount of vibration that brings the active vibration compensation to zero by introducing counter-torques. One possible compensation target for a printing press is, for example, the deviation of the rotational speed of the first printing cylinder from a desired speed. If the vibration compensation is switched on, this oscillation measure would be for the order being combated almost zero. The underlying theory is that only one compensation target can be achieved with a single motor. It has been found that a particularly advantageous compensation target is the difference path between or the difference of the amplitudes at the two measuring points mentioned above. That is, the active vibration compensation initiates counter-moments such that the difference path between or the difference of the amplitudes at the two measuring points goes to zero.

For the preferred embodiment of the inventive active vibration compensation in a single machine, the transfer function (also referred to as frequency response) between the engine torque and the compensation target is measured in a single initialization run. The transfer function is therefore available in the machine software after this measurement.

During operation of the machine, in particular printing operation, the active vibration compensation monitors certain frequency components or order components of the vibration signal defined as the compensation target. An algorithm calculates the counter-torque such that the compensation target goes to zero. Such algorithms, which are particularly advantageous, are for example in the document DE 101 49 525 A1 or in the document US 6,796,183 B2 as well as in the document DE 102 17 707 A1 or in the document US 2003/0230205 A1 accessible to the skilled person. In the case of unfavorable constellations of the location and frequency of the disturbance, as well as motor positions and sensor positions, the monitored compensation target is regulated to zero, but at other measuring points in the machine the oscillation amplitudes increase due to active vibration compensation. According to the invention, it is therefore provided in these embodiments to selectively switch on and off the active vibration compensation.

Switching on and off can be done according to different criteria. It has been shown that a particularly advantageous criterion can be formulated via the measured transfer function between the engine torque and the compensation target. The active compensation is therefore only turned on when the amplitude the transmission function at the current oscillation frequency exceeds a set threshold, for example 10%, 30% or 50% of its maximum value.

1 shows schematically a section of an embodiment of a printing material processing machine 1, in particular a printing press with a plurality of printing units 2 and cylinders 3, with a control device and an inventive active vibration compensation for a cylinder. The substrate processing machine 1 of this embodiment may have either a continuous gear train or a broken gear train. The use of a compensation device 9 according to the invention and the use of a control device according to the invention with control element 8 and compensation device 9 is not limited to the reduction of vibrations at transfer points between sheet-guiding cylinders, but can generally improve the control or compensation of vibrations of cylinders, such as printing forme cylinder, Transfer or blanket cylinder or impression cylinder, as well as rollers and rollers in inking and / or dampening can be used. An example of a control with parallel compensation for a first cylinder 4 is shown in FIG. 1: An angular position sensor generates a representative signal for the progression of the angular size (time profile of the value of the angular size) and supplies it to the control element 8 together with an angular size setpoint 10 , The control element 8 may be a simple differential controller or else a controller which comprises complicated transformations (integrations, differentiations and the like). The representative of the course of the angular size signal is also supplied to the compensation element 9 in parallel. Its output signal is superimposed on the output signal of the control element 8 at the subtraction point after the control element 8. The superposed signal is supplied to the first actuator 6. Since the frequency to be compensated or the frequencies of the compensation element 9 to be compensated are adjustable, vibrations of an integer order can be compensated in addition to vibrations of non-integer order in comparison to the machine frequency. According to the invention now the compensation element 9 of the control device is designed such that it in Depending on the result of the comparison of the measure of the sensitivity of the machine with the threshold value is switched on or off or will.

2 is a schematic section of an alternative embodiment of a substrate-processing machine 1, in particular a printing press, which comprises a plurality of printing units 2 and 3 cylinder, with separate gear train, two control devices and two Schwingungskompensationen invention. In this embodiment, to compensate for vibrations at a transfer point between two sheet-guiding cylinders, on the one hand, a separate compensation for the first cylinder 4 and for the second cylinder 5, but on the other hand, a relative compensation for the angular difference, shown here by way of example for the second cylinder 5 , carried out. This embodiment advantageously combines an absolute reduction of the vibrations with the relative reduction of the vibrations (relevant arc transfer angular size). The first cylinder 4 is associated with a control element 8, to which a representative signal for the angular size of the first cylinder 4 (value of the angular size) and an angular size setpoint 10 are supplied. Parallel to the control element 8, a compensation element 9 is provided, whose output signal is superimposed on the output signal of the control element at the subtraction point after the control element 8. The superposed signal is supplied to the first actuator 6. The second cylinder 5 is also associated with a control element 8 to which a representative signal for the angular size of the second cylinder 5 (value of the angular size) and an angular size setpoint 10 are supplied. The difference angle between cylinder 4 and cylinder 5 or one of them linearly dependent size, a measure of the difference angle, is fed to the compensation element 9 at a subtraction point. The output signal of the compensation element 9 is superimposed on the output signal of the control element 8 at a subtraction point after the control element 8 of the second cylinder 5. The superposed signal is supplied to the second actuator 7.
According to the invention, the compensation elements 9 of the regulating device are now designed such that they are switched on or off depending on the result of the comparison of the measure of the sensitivity of the machine with the threshold value.

FIG. 3 schematically illustrates the significance of the threshold value according to the invention for switching the active vibration compensation on and off in a preferred embodiment of the method according to the invention.

In the partial image A of FIG. 3, vibration amplitudes as a function of the frequency are plotted in applicable units (a.u.). On the one hand, vibration amplitudes 11 are shown which are measured without compensation, that is to say with active vibration compensation switched off, at a specific frequency, which are measured in particular at a specific value of an operating parameter, such as, for example, the printing speed. These have a maximum at a certain first frequency, on the other hand, vibration amplitudes 12 are shown, which are measured with compensation, that is, with activated active vibration compensation. It can be clearly seen that these oscillation amplitudes now have a maximum at a certain second frequency, which is higher than the first one. At the same time, the oscillation amplitudes 12 at the first frequency are significantly reduced compared to the oscillation amplitudes 11. Thus, while the compensation target can be met, on the other hand the substrate processing machine oscillates at a different frequency, but at a lower amplitude, especially if the substrate processing machine is on operated at a different value of the printing speed.

In the partial image B of Figure 3, the amount of the amplitude of the required counter-torque 13 or compensation torque in applicable units (applicable units, a.u.) Plotted as a function of frequency. It can be seen that the required counter-torque 13 in the region of the second frequency is particularly large, so that an excitation of the printing material-processing machine can take place.

In sub-picture C of FIG. 3, the transfer function 14 or the frequency response from the compensation torque to the compensation variable, the compensation target, is shown in applicable units (au). There is a threshold 15 set.

Now, if the amplitude of the transfer function 14 exceeds this threshold 15, in particular at least one frequency, in this embodiment, the active vibration compensation is turned on. The excess takes place in a compensation window 16, in a frequency interval which, as can be seen from the partial image A, includes the maxima occurring at the first frequency.

LIST OF REFERENCE NUMBERS

1

Substrate processing machine

2

printing unit

3

cylinder

4

first cylinder

5

second cylinder

6

first actuator for controlling the first cylinder

7

second actuator for controlling the second cylinder

8th

control element

9

compensator

10

Angle variable setpoint

11

Oscillation amplitude without compensation

12

Oscillation amplitude with compensation

13

counter-torque

14

transfer function

15

threshold

16

compensation window

Claims (14)

Method for active compensation of vibrations in a printing machine (1) in which at least one signal which contains a vibration of the machine or a part of the machine is measured and at least one counter-torque (13) for reducing the vibration in the machine ( 1) is introduced,
characterized,
in that at least one measure of the ratio between the amplitude of the uncompensated oscillation and the amplitude of the counter-torque (13) necessary for complete compensation is compared with a threshold value (15) and the counter-torque (13) to be introduced is determined in a first functional relationship with the oscillation if the measure is greater than the threshold value (15), and the counter-torque (13) to be introduced is determined in a second functional relationship with the vibration other than the first functional relationship, if the measure is less than the threshold value (15). is. Method for active compensation of vibrations according to claim 1,
characterized,
that the value of the counter-torque (13) to be introduced in the second functional relationship is substantially zero. Method for the active compensation of vibrations according to claim 1 or 2,
characterized,
that the counter-torque (13) is switched to a drive torque of the machine. Method for active compensation of vibrations according to one of the preceding claims,
characterized,
that is used as a measure of the amplitude of the transfer function (14) between the counter-torque (13) and the oscillation and is compared, whether the transfer function (14) exceeds the threshold value (15) at least one frequency. Method for active compensation of vibrations according to one of the preceding claims,
characterized,
in that for initialization the transfer function (14) between the counter-torque (13) and the oscillation is measured. Method for active compensation of vibrations according to one of the preceding claims,
characterized,
that the location of measurement of the vibration of the machine or a part of the machine at the first frequency, and the point of introduction of the counter-torque (13) for reduction of the vibration do not coincide. Method for active compensation of vibrations according to one of the preceding claims,
characterized,
in that the printing material processing machine (1) is driven or controlled to an operating frequency. Method for active compensation of vibrations according to one of the preceding claims,
characterized,
that the amplitude and the phase of the oscillation are determined from the measurement. Method for active compensation of vibrations according to one of the preceding claims,
characterized,
that the counter-torque is determined by means of a filter which has a transfer function with a frequency parameter which corresponds to the frequency of the oscillation to be compensated. Method for active compensation of vibrations according to one of the preceding claims,
characterized,
in that the oscillation is a vibration of a machine shaft or a signal value difference of two or more than two machine shafts or an eigenmode of the printing material processing machine (1) or an eigenmode of a part of the printing material processing machine (1). Method for active compensation of vibrations according to one of the preceding claims,
characterized,
that the frequency of the oscillation is a non-integer multiple of an operating frequency of the printing material processing machine. Method for active compensation of vibrations according to one of the preceding claims,
characterized,
that the method is applied to a plurality of oscillations of different frequency. Substrate processing machine (1) with a control device for active compensation of vibrations in the printing material processing machine (1),
characterized,
that the control means for carrying out a method according to one of the preceding claims is pronounced and when the measure of the ratio between the amplitude of the uncompensated oscillation and the amplitude of the time necessary for complete compensation counter-torque (13) is greater than the threshold value (15), in operable in a first mode and, if the measure of the ratio between the amplitude of the uncompensated oscillation and the amplitude of the counter-torque (13) necessary for complete compensation is less than the threshold (15), is operable in a second mode. Substrate processing machine (1) according to claim 13,
characterized,
that the machine is a printing machine, a printing form or print processing machine.

Images