EP0741031A2 - Method and device for measuring the dynamic properties of the colour zones in inking units of a printing machine - Google Patents

Abstract

A printed document is scanned with a camera that provides voltage signals indicative of the various colours. The values are used in a sensitivity matrix that is used to regulate the colour characteristics of different zones. The response of the system to a sudden change in operating condition (S) produces a measured signal that responds after a delay (T) with an exponential characteristics. The initial rate of change of the signal allows identification of the dynamic characteristic to be made.

Description

The invention relates to a method for determining the dynamic properties of controlled systems in color zones of inking units of a printing press forming control loops.

In order to achieve optimal control results in the color control of printing presses, the dynamic properties of the controller must be adapted to the route. Optimal control results mean a minimal settling time for setpoint changes and the fastest possible correction of faults. In the control system mentioned, the controlled system consists of the ink zone of a printing unit of the printing press. The controlled variable is determined by measurement and compared with a reference variable. The controlled variable represents an actual value and the reference variable represents a desired value. The control deviation determined from the comparison of the actual value and the desired value is fed as a manipulated variable to a controlled system via a controller and an actuator. The control loop has a measuring device which detects the actual value and feeds it to a comparison element in order to determine the control deviation in comparison with the setpoint value. In accordance with the determined control deviation, the controller actuates an actuator that acts on the controlled system. In the present case, the controlled system is formed by the ink zone of the inking unit, that is to say the thickness of the gap in the ink zone is set by means of a suitable actuator, so that a corresponding ink layer thickness is obtained on the printed copy.

For the necessary adaptation of the controller to the dynamic properties of the controlled system, it is necessary to set the control parameters. To determine the control parameters, the controlled system is adapted by means of a suitable model and the optimal controller and the corresponding parameters are defined for this. The controllers can have different time behavior. For example, P controllers, PI controllers, PD controllers, PID controllers or I controllers can be used. To identify the controlled system, the reaction to a sudden change in the manipulated variable is analyzed. There is then a so-called step response or transition function. In the case of controlled systems with relatively constant behavior, this can be identified according to the above procedure, which is preferably carried out once when the system is installed. With regard to the controlled systems under consideration here, namely the aforementioned printing unit zones that can be changed in the zone opening, there is no such constant behavior, since the dynamic properties can change from print job to print job, even within a print job. Setting the control parameters in advance during installation is therefore unsatisfactory. The route must be "taught" anew with each print job. Before the actual print job begins, the transition function necessary for adjusting the controller must therefore be determined, but this entails very large amounts of waste. Otherwise, in such a case the dynamic properties of the controlled system can only be determined at the time of the determination; Changes that occur during the print job are not taken into account. If one were to fall back on the "natural" manipulated variable changes during the print job, the following problems arise: Several simultaneous or approximately simultaneous adjustments in different printing units lead to overlaps and / or two or more shortly executed Adjustments on a printing unit also involve overlays. As a result, these overlaps can no longer be separated from one another, so that identification of the dynamic properties of the controlled system is impossible.

The invention is therefore based on the object of specifying a method for determining the dynamic properties of ink zones of inking units of a printing press, in which there is little or no waste and overlapping problems are overcome.

This object is achieved in that the jump responses that occur during printing to complete a print job due to changes in the manipulated variables - even if adjustments and thus jump responses overlap in different printing units of the printing press and / or sufficiently briefly carried out and thus superimposed adjustments and thus superimposed jump responses of a printing unit are exposed to a known sensitivity matrix in order to disentangle the overlays for recognizing the individual dynamic behavior of each or the inking unit. Consequently, the sensitivity matrix known to the person skilled in the art from the color control is used in order to infer the dynamic behavior of the controlled system from the measured information, namely from the natural step responses. The sensitivity matrix represents a relationship between the measured values and the controlled systems (manipulated variables).

With regard to its adjustable zone opening, the respective controlled system represents an influence on the ink layer thickness of the printed copy. If the measured ink layer thickness is linked to the sensitivity matrix as a representative measured value, the result is independent of the result from possible considerations to the transfer functions of individual printing units. The respective measured value, for example a voltage value, is measured using a camera that optically monitors the subject. This voltage value is functionally related to the controlled system variables. The functional relationship is formed by the sensitivity matrix M mentioned. Since the sensitivity matrix is known from the color control of the printing press, it is used according to the invention to determine the dynamic properties of individual controlled systems. The measured values determined during the optical measurement are quasi unbundled from possible superimpositions of several adjustments, i.e., simultaneous or approximately simultaneous changes in the zone openings in several inking units and / or a simultaneous or immediately successive change in the zone opening of an inking unit can be broken down, so that the dynamic properties for each ink zone of each inking unit can be clearly determined. The associated controller can then be optimally selected / set with regard to its control parameters.

In contrast to the known method, the determination of the dynamic properties of the subject matter of the invention is carried out during the print job, that is, not in an upstream process, and naturally occurring changes in the manipulated variables are used, that is to say, no deliberately brought about in order to obtain the jump responses. This means that there is no waste and that the dynamic properties can be determined repeatedly during the entire processing time of a print job, so that any changes in these properties that may occur can be reacted to, if desired.

According to a development of the invention, it is provided that the respective step response is determined by optically measuring the reflectance of the associated printing ink on the printed copy. For this purpose, the above-mentioned camera is used, which is preferably provided with four filters (X, Y, Z and IR), so that the colors red, green, blue and infrared information can be scanned by means of these four channels. The camera thus allows measured values to be obtained in relation to a specific color of an inking unit, a specific color zone of this inking unit being addressed depending on the location of the determination on the subject.

Furthermore, it is advantageous if, of the step response, only the dead time between the start of the manipulated variable change and the start of the change in ink layer thickness and the maximum gradient of the transition function that occurs are used. This procedure therefore does not require the complete recording of the step response by means of the measurement. This enables a quick intervention or, if the step response is not completely available for certain reasons, it is sufficient to determine the dynamic properties, determine the dead time and determine the maximum gradient of the transition function. Dead time is to be understood as the time that elapses between a change in the manipulated variable and the reaction to it in the form of a changing ink layer thickness on the subject. The response time (dead time) is therefore determined by the unwinding length of the inking unit, which means that the inking unit geometry plays a decisive role. The maximum gradient of the transition function that occurs, i.e. the greatest change in the assumption of the new state of the ink layer thickness, is a measure of the total response time, that is to say the time that passes until a new stable state is reached. The identification of the controlled system can be determined by means of these two values on the basis of reduced system parameters, one also Estimation of the dead time and the maximum gradient of the transition function can be carried out.

Furthermore, it is advantageous if the optical measurement is carried out, as already mentioned, in a camera system which determines a measured value for each of the printing inks used for the separate detection. As already mentioned, this can be a voltage value that is functionally related to the color layer thickness.

Fig. 1

eine schematische Darstellung einer Anordnung zur Durchführung des Verfahrens,

Fig. 2

ein Flußdiagramm des Verfahrens und

Fig. 3

ein Diagramm, das aufgrund einer Stellgrößenänderung die zugehörige Sprungantwort wiedergibt.

The drawings illustrate the invention using an exemplary embodiment, namely:

Fig. 1

1 shows a schematic representation of an arrangement for carrying out the method,

Fig. 2

a flowchart of the process and

Fig. 3

a diagram that shows the associated step response due to a change in the manipulated variable.

FIG. 1 shows a print copy 1 located in a printing machine, not shown, which is optically scanned by means of a camera 2. The camera has four filters, not shown, to determine the colors red, green, blue and infrared information.

The camera 2 detects the reflectances of the various printing inks and preferably uses them to form voltage values which are applied as measured values to the known sensitivity matrix M used in color control. In this way, the dynamic properties of the individual ink zones of the inking units can be determined, the dynamic properties being monitored during the ongoing printing process and as a basis for renewed printing Adaptation of the controller can be used by changing the parameters accordingly.

The method steps to be carried out are explained on the basis of FIG. In step 4, the measured values are determined by means of the camera 2. In step 5, the sensitivity matrix M is applied to the measured values, so that, as step 6-, information about the routes is available which allows the dynamic properties to be individually separated to recognize any considerations.

FIG. 3 uses a diagram to explain a change in a manipulated variable S at time t1. This change in the manipulated variable leads to a readjustment with regard to the ink layer thickness of the subject, with a dead time T initially beginning from time t1 to time t2, during which no reaction has yet taken place. At time t1, the system reacts to the change in the manipulated variable, for example with an exponential increase in the thickness of the ink layer, until - at time t3 - a new steady state is reached. The maximum gradient of this transition function, which is determined by the angle, can be used together with the dead time T in order to identify the controlled system.

By means of the invention, the transfer function from adjustments of several printing units or adjustments of a printing unit can thus be assigned to the individual printing units by using the sensitivity matrix M used in the regulation. Furthermore, the identification of the controlled system is determined by the dead time and the maximum gradient of the transition function, it also being possible to estimate the dead time and the gradient.

Reference list

1

Printed copy

2nd

camera

3, 4, 5, 6

steps

M

Sensitivity matrix

S

Manipulated variable

Ü

Transition function

T

Dead time

t1, t2, t3

Time points

Claims (4)

Method for determining the dynamic properties of controlled systems in color zones of inking units of a printing press forming control loops,
characterized,
that the jump responses that occur during printing to complete a print job due to changes in the manipulated variables - even if adjustments and thus jump responses overlap in different printing units and / or there are sufficiently briefly performed and thus overlaid adjustments and thus overlapping jump responses of a printing unit - with a known sensitivity matrix ( M) are applied in order to disentangle the superimpositions for recognizing the individual dynamic behavior of each or the inking unit. Method according to claim 1,
characterized,
that the respective step response is determined by optical measurement of the reflectance of the associated printing ink on the printed copy. Method according to one of the preceding claims,
characterized,
that only the dead time (T) lying between the start of the manipulated variable change and the start of the change in ink layer thickness and the maximum gradient of the transition function (Ü) are used of the step response. Method according to one of the preceding claims,
characterized,
that the optical measurement is carried out with a camera system (camera 2) which determines a measured value for the separate detection of each of the printing inks used.

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