The present invention relates to a printing machine having a ductor roller.
In printing machines having a ductor roller, the ductor roller is provided between a fountain roller and an ink transfer roller. The ductor roller is a roller divided into multiple individual rollers along its axis, and the duty ratio at which the individual rollers contact on the fountain roller is controllable independently for the individual rollers. Further, the printed density on the printed product is measured for each color component, and the individual rollers in the ductor roller are feedback controlled so that the printed density is in agreement with the desired density. With the feedback control, the variations in printed density during printing is reduced (Patent Document 1: JP 2015-63071A, corresponding to U.S. Pat. No. 9,446,581).
The ductor roller has an amount of ink drawn from the fountain roller, and ink transfer rollers also have an amount of ink. Because of the ink reservation on the rollers, the control of printed density by means of the ductor roller has a delay time. To reduce the delay time, it has been proposed to increase temporarily the amount of ink feeding to the ductor roller when the printing plate is exchanged and the new image area ratio in the new printing plate is increased, and also to decrease temporarily ink feeding amount to the ductor roller when the new image area ratio is decreased (Patent Document 1: JP 2015-63071A, corresponding to U.S. Pat. No. 9,446,581).
Patent Document 1: JP 2015-63071A, corresponding to U.S. Pat. No. 9,446,581
The control data of the ductor roller is made optimistic with monitoring the printed density and feeding back it to the ductor roller. However, it has not been considered in the conventional art how to utilize the resultant control data of the ductor roller to improve printing quality on the next or a subsequent day. For instance, when the same printing plate is to be used on the next day, the data which is resultant today will be also usable on the next day. However, this is a rare case, and when a new printing plate is to be used for printing on the next day, it has not been considered how the old control data resultant till the previous day may be utilized in the subsequent day.
Since old data for an old printing plate may not be utilized, for each exchange of printing plate, it is necessary to monitor printed density and to wait until the printing conditions reach within an allowable range. This increases loss papers before the printed density reaches within an allowable range. Further, since inexperienced operators generate more loss papers, printing jobs have to depend heavily upon experienced operators.
The object of the invention is to adjust control data for the ductor roller with learning by an adjustment apparatus so as to
The printing machine according to the present invention has a ductor roller and comprises an ink fountain, a fountain roller in contact with the ink fountain, the ductor roller, at least an ink transfer roller, and a controller configured and programmed to control the ductor roller.
Said ductor roller is provided with multiple individual rollers arranged along an axis direction of the ductor roller.
The time durations during which the individual rollers are in contact with the fountain roller are referred to as contact time τ; a period for controlling the individual rollers between positions in contact with and not in contact with the fountain roller is referred to as a control period T1; and said controller is configured and programmed to control individually duty ratios of the individual rollers, said duty ratios consisting of ratios τ/T1 of the contact time to the control period, in order to control individually ink feeding amounts by the individual rollers.
Parameters for the individual rollers indicating desired ink feeding amounts by the individual rollers are referred to as individual graph data gr; initial values of the individual graph data gr are referred to as gri and are determined according to images to be printed; an average of the individual graph data gr over the whole of the ductor roller is referred to as an averaged graph data g; and an initial value of the averaged graph data g is referred to as gi. Said controller is configured and programmed to control the duty ratios of the individual rollers based upon the individual graph data gr and to change the individual graph data gr so as to cancel errors between measured printed densities and desired printed densities or according to an input by an operator.
The printing machine is further provided with an adjustment apparatus for adjusting said duty ratios.
The adjustment apparatus is configured and programmed:
wherein a stable value of the averaged graph data g is referred to as ge and stable values of the individual graph data gr are referred to as gre;
to collect data including the initial value gi and the stable value ge both of the averaged graph data g, and the initial values gri and the stable values gre both of the individual graph data gr;
to update a basic parameter B based upon a difference between a distribution of the stable values ge and a distribution of the initial values gi both of the averaged graph data in the collected data;
wherein the collected data are classified into multiple printing speed regions according to printing speeds;
to update individually speed parameters V which are parameters in the individual printing speed regions, based upon differences between distributions of the stable values ge and distributions of the initial values gi both of the averaged graph data in the individual printing speed regions;
wherein the collected data are classified into multiple regions according to the averaged graph data g;
to update individually area parameters F which are parameters in the individual regions according to the averaged graph data g, based upon differences between distributions of the stable values ge and distributions of the initial values gi in the individual regions according to the averaged graph data g;
to process the collected data individually for the individual rollers and to update individually roller parameters R which are parameters for the individual rollers, based upon differences between distributions of the stable values gre and distributions of the initial values gri both of the individual graph data;
to change collectively the duty ratios of the individual rollers, based upon three parameters of the updated basic parameter B, an updated speed parameter V corresponding to a printing speed for a present printing job, and an updated area parameter F corresponding to an averaged graph data in the present printing job; and
to change individually the duty ratios of the individual rollers, based upon the updated roller parameters R corresponding to the individual rollers.
The adjustment apparatus for a printing machine and the adjustment method both according to the present invention adjust the below described duty ratios of a printing machine having a ductor roller and comprising an ink fountain, a fountain roller in contact with the ink fountain, the ductor roller, at least an ink transfer roller, and a controller configured and programmed to control the ductor roller,
wherein said ductor roller is provided with multiple individual rollers arranged along an axis direction of the ductor roller,
wherein time durations during which the individual rollers are in contact with the fountain roller are referred to as contact time τ, a period for controlling the individual rollers between positions in contact with and not in contact with the fountain roller is referred to as a control period T1, and wherein said controller is configured and programmed to control individually duty ratios of the individual rollers, said duty ratios consisting of ratios τ/T1 of the contact time to the control period, in order to control individually ink feeding amounts by the individual rollers;
According to the invention, the adjustment apparatus carries out the following steps:
wherein a stable value of the averaged graph data g is referred to as ge and stable values of the individual graph data gr are referred to as gre;
collecting data including the initial value gi and the stable value ge both of the averaged graph data g, and the initial values gri and the stable values gre both of the individual graph data gr;
updating a basic parameter B based upon a difference between a distribution of the stable values ge and a distribution of the initial values gi both of the averaged graph data in the collected data;
classifying the collected data into multiple printing speed regions according to printing speeds;
updating individually the speed parameters V which are parameters in the individual printing speed regions, based upon differences between distributions of the stable values ge and distributions of the initial values gi both of the averaged graph data in the individual printing speed regions;
classifying the collected data into multiple regions according to the averaged graph data g;
updating individually area parameters F which are parameters in the individual regions according to the averaged graph data g, based upon differences between distributions of the stable values ge and distributions of the initial values gi in the individual regions according to the averaged graph data g;
processing the collected data individually for the individual rollers and individually updating roller parameters R which are parameters for the individual rollers, based upon differences between distributions of the stable values gre and distributions of the initial values gri both of the individual graph data;
changing collectively the duty ratios of the individual rollers based upon three parameters of the updated basic parameter B, an updated speed parameter V corresponding to a printing speed for a present printing job, and an updated area parameter F corresponding to an averaged graph data in the present printing job; and
changing individually the duty ratios of the individual rollers based upon the updated roller parameters R corresponding to the individual rollers.
According to the invention, the following functions and advantageous merits are resultant:
The basic parameter B is applied to all the individual rollers. With respect to the area parameters F, the parameter in the region to which the averaged graph data for the present printing job belongs to is applied. With respect to the speed parameters V, the parameter in the region to which the printing speed for the present printing job belongs to is applied. The roller parameters R are parameters provided separately for the individual rollers. The stable values gre of the individual graph data gr are measured for example simultaneously with the stable value ge of the averaged graph data g. In the specification, descriptions about the printing machine are applicable to the adjustment apparatus and to the adjustment method as they are. The differences between the distribution of the stable values and the distribution of the initial values are intended to mean the differences between the average of the stable values and the average of the initial values, the differences between the median of the stable values and the median of the initial values, and so on. The difference between the distributions may be dealt with simply as the difference in the averages or the ratio of the averages, and the difference in the averages and the ratio of the averages represent substantially the same factor.
Preferably, the adjustment apparatus is configured and programmed:
to increase the basic parameter B when an average of the difference ge−gi between the stable value and the initial value both of the averaged graph data is positive, and to decrease the basic parameter B when the average of the difference ge−gi between the stable value and the initial value both of the averaged graph data is negative;
to increase individually the speed parameters V when the averages of the differences ge−gi between the stable values and the initial values both of the averaged graph data are positive in the individual regions of the printing speeds, and to decrease individually the speed parameters V when the averages of the differences ge−gi between the stable values and the initial values of the averaged graph data are negative in the individual regions of the printing speeds, wherein the speed parameters V indicate parameters in the individual printing speed regions, when the collected data are classified into the printing speed regions according to printing speeds;
to increase individually the area parameters F when averages of the differences ge−gi between the stable values and the initial values both of the averaged graph data are positive in the individual regions of the averaged graph data g, and to decrease individually the area parameters F when the averages of the differences between the stable values of the averaged graph data and the initial values of the averaged graph data ge−gi are negative in the individual regions of the averaged graph data g, with respect to the area parameters F for the individual regions of the averaged graph data g into which the collected data are classified;
to process individually the collected data for the individual rollers and to increase individually the roller parameters R when averages of differences gre−gri between the stable values and the initial values both of the individual graph data are positive and to decrease individually the roller parameters R when the averages of differences gre−gri between the stable values and the initial values both of the individual graph data are negative, with respect to the roller parameters R for the individual rollers;
to increase the duty ratios of all the individual rollers when three parameters of the updated basic parameter B, an updated speed parameter F corresponding to the printing speed for a present printing job, and an updated area parameter F corresponding to an averaged graph data g in the present printing job are larger than 1 and to decrease the duty ratios of all the individual rollers when all of said three parameters are smaller than 1; and
to increase individually the duty ratios of the individual rollers when the updated roller parameters R for the individual rollers are larger than 1 and to decrease individually the duty ratios of the individual rollers when the updated roller parameters are smaller than 1.
When two of the basic parameter B, the speed parameter V, and the area parameter F are larger than 1 and the remaining one parameter is smaller than 1, or when a similar situation has occurred, the duty ratio is controlled by a majority rule among the B,V,F. For example, the product (B·V·F) of the three parameters is compared with 1, and when the product (B·V·F) is larger than 1, the duty ratios of all the individual rollers are increased. When the product (B·V·F) is smaller than 1, the duty ratios of all the individual rollers are decreased. Further, the positive or the negative of ge−gi indicates the same thing to whether ge/gi is larger than 1 and to whether gi/ge is smaller than 1. The average is one resultant over the collected data, and to get the average, every data may be used or some unreliable data deviated from the center of the data distribution may be excluded. Further, with respect to the update of the speed parameters V, the collected data are sorted into the regions according to printing speeds, and with respect to the update of the area parameters F, the collected data are sorted into the regions according to averaged graph data. The initial values gri of the individual rollers may be determined according to the image to be printed such that the initial values gri are determined according to image area ratios with respect to the individual ductor rollers, for example.
Preferably, said adjustment apparatus is configured and programmed with respect to the three parameters of the basic parameter B, the speed parameters V, and the roller parameters R, to evaluate only the collected data where the averaged graph data g is not less than a first predetermined value and not to evaluate the collected data where the averaged graph data g is less than the first predetermined value; and with respect to the area parameters F, to evaluate both the collected data where the averaged graph data g is not less than the first predetermined value and the collected data where the averaged graph data g is less than the first predetermined value. When the averaged graph data is small, the printed density may be unstable; therefore, only the data where the graph data is equal to or larger than the predetermined value are used in such a way that the basic parameter B, the speed parameters V, and the roller parameters R are altered in a highly reliable manner On the contrary, with respect to the area parameters which should cover a wide range of the graph data regions, the data where the graph data is less than the predetermined value are also evaluated.
Preferably, said adjustment apparatus is configured and programmed to update four parameters of the basic parameter B, the speed parameters V, the area parameters F, and the roller parameters R to cancel only partly the differences between the distributions of the stable values ge and the distributions of the initial values gi both of the averaged graph data or to cancel only partly the differences between the distributions of the stable values gre and the distributions of the initial values gri both of the individual graph data. With the iterative updates of the adjustment parameters, the parameters approach to the optimistic values asymptotically and do not oscillate.
Preferably, said adjustment apparatus is configured and programmed to adjust the graph data ge, gi, gre, or gri when changing one parameter of the basic parameter B, the speed parameters V, the area parameters F, and the roller parameters R so as to adjust influence by the change in said one parameter, and to adjust other parameters based upon the adjusted graph data ge, gi, gre, or gri. In this algorithm, since errors already treated by other parameters are not treated once more by another parameter, over adjustments do not occur.
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The best embodiment for carrying out the invention will be described in the following. The embodiment does not restrict the scope of the invention. The scope of the invention is determined according to accompanying claims in consideration with well-known matters in the art and in consideration with construction by an ordinary person in the art.
An adjustment apparatus 20 outputs adjustment parameters to the feedback apparatus 15. The adjustment parameters comprise four species of parameters: a basic parameter B for adjustment of variations in printed density (hereinafter referred to as “density”) according to the species of the ink and the conditions of the unit 10; speed parameters V for adjustment of variations in density according to printing speeds; area parameters F for adjustment of variations in density according to the values of the graph data; and roller parameters R for adjustment of variations in density according to the conditions of individual rollers 7. Further, other parameters, such as one for dealing with the properties of printing sheets, may be added. These parameters are dependent upon and meaningful for the combination of unit 10, the printing sheets, and the ink. When one combination has been used in a printing job in the past, the initial values for the parameters B, V, F, R may be determined according to the graph data in the past printing job. When the combination is new and has not been used in the past, the initial values for the parameters B, V, F, R may be set one, or parameters B, V, F, R resultant in a similar combination may be used as the initial values for the parameters B, V, F, R.
The exchange of a roller, cleaning of the water tank, and so on influence greatly the conditions of the print unit 10. When the conditions of the print unit 10 have greatly changed, it is advantageous to initialize the parameters B, V, F, R.
The adjustment apparatus 20 consists of an adequate computer and is a part of the printing machine 1. However, when a host computer controls multiple printing machines via LAN, the adjustment apparatus 20 may be provided within the host computer. The adjustment apparatus 20 monitors the changes in the graph data in the controller 18 and makes a memory 21 to store the graph data files in
The adjustment apparatus 20 updates the adjustment parameters, for example, when ending one day's printing jobs, and stores the transitions of the adjustment parameters' values (for example, the initial and the present values). Changes in the conditions of the print unit 10 cause the update of the adjustment parameters. The accumulated values of the changes in the adjustment parameters indicate the changes in the conditions of the print unit 10. Therefore, the accumulated values of the changes in the adjustment parameters are advantageously indicated on the display 32 so that the operator may notice the changes in the conditions of the print unit 10.
Update means for the basic parameter is indicated 22; update means for speed parameters is indicated 24; update means for area parameters is indicated 26, and update means for roller parameters is indicated 28. An adjustment means 30 inputs the updated parameters to the controller 18, and the controller 18 adjusts the duty ratios for the “on” for the individual rollers 7 according to the product kr of these parameters.
The number of sorted files is confirmed not less than a second predetermined value (for example 2). Further, it is confirmed that the distribution of d (d=ge/gi) is not symmetrical around 1 and deviated from 1 to the area where d is larger than 1 or to the area where d is smaller than 1 (steps 3,4). The factor d indicates the degree of adjustment to the graph data at the startup (graph data when printing jobs started) by the feedback apparatus 15; when d>1, the graph data has been increased, and when d<1, the graph data has been decreased. Further, individual d values exist for the individual files. When the file number is small, the reliability of the data is low, and when the distribution of d is symmetrical around 1, the update of the basic parameter is not needed. However, the confirmation that the distribution of d is not symmetrical around 1 may be omitted.
When there are multiple files whose graph data are not less than the first predetermined value, and when the distributions of d in the files are deviated from 1 to the area where d is larger than 1 or to the area where d is smaller than 1, the basic parameter B is updated. The new basic parameter is set using the average A(d) of d,
Bnew=Bold×(1+(A(d)−1)a) (step 5).
Here, “a” is an adjustment factor and 0<a<1, “Bold” is the basic parameter before the update, and “Bnew” is the basic parameter after the update. Instead of canceling completely the error in the basic parameter B, the error is partly removed for each update so that the basic parameter B reaches asymptotically an adequate value through iterative updates. The change by one update is determined by (A(d)−1)a, and there may be an upper limit for the absolute value of (A(d)−1)a. After B is updated, as a preparation for updating other parameters, such as the speed parameters, with respect to the graph data where B has been updated, the value of ge is replaced with
ge2=ge/(1+(A(d)−1)a) (step 6).
The speed parameters are updated in a similar way to the basic parameter B (step 15). A certain upper limit for the change due to the update may be provided. Further, for the next update of area parameters, the value of ge2 is replaced with
ge3=ge2/(1+(D2−1)b) (step 16).
In step 25, the area parameters F are updated in a similar way to the basic parameter B and so on. In step 26, as a preparation for the update of the roller parameters, ge3 is replaced with ge4 in such a way that ge4=ge3/(1+(E2−1)f). Further, with respect to the update of area parameters, when the insufficiency of the file number causes a delay of the update, the update may promptly be performed as if graph data files are present for the individual rollers 7.
The graph data files store the startup values gri of the graph data and the values gre at the end of a printing job for the individual rollers. When updating parameters B, V, F, the graph data gre are replaced in a similar way to the graph data ge in steps 6, 16, and 26 in
In
According to the embodiment, the adjustment parameters are made optimized through the iterative updates. In other words, the updates are restricted by certain conditions so that the adjustment parameters do not oscillate due to an excessive update or due to an update based upon an unreliable data. For example, the following restrictions are applied:
the existence of multiple effective files;
usage of graph data not less than the first predetermined value (for the parameters B,V,R);
the adjustment factors between 0 and 1;
the upper limit for the absolute values of the changes by updates; and
the smooth changes in the parameters according to the speed regions and area regions (for the parameters V, F). When oscillations of the parameters are acceptable, these restrictions may be omitted.
Among the conditions on the updates, for the updates of the basic parameter B, the speed parameters V, and the roller parameters R, it is important that files whose graph data are less than the first predetermined value should not be used. For the updates of the parameters B, V, F, R, it is important that, if there are not multiple effective files, the updates should not be done. Further, it is also important to make the parameters reach the optimistic values asymptotically through the multiple updates by restricting the adjustment factors between 0 and 1 or by setting the upper limits to the changes in the parameters.
Returning to
In the embodiment, while the four parameters are multiplied, it is enough if the adjustment factor for the duty ratio is determined by a function of the four parameters; the operation is not limited to multiplication. The four parameters may be updated independently; for example, without updating the area parameters F due to the lack of sufficient data, the other three parameters may be updated. When printing sheets are changed or when ink is changed, according to the embodiment, the adjustment parameters before the change is not used. However, the adjustment parameters before the change may still be used. For instance, the speed parameters V for adjusting the dependency on the speed of the printing machine and the roller parameters R adjusting the dependency upon individual rollers may be used without change from the previous parameters after changing the printing sheets or changing the ink.
According to the embodiment, the feedback apparatus 15 learns how the graph data have been altered and determines the adjustment parameters. According to the embodiment, the following advantageous merits are resultant:
The parameters B, V, F, R are determined upon the combination of the print unit, the printing sheets, and the species of ink. There are some occasions that the graph data files in
those parameters B, V, F, R that are for a similar print unit and for the same ink and for the same printing sheets;
those parameters B, V, F, R that are for printing sheets having a similar sheet properties and for the same ink and for the same printing unit; or
those parameters B, V, F, R that are for a similar ink in the ink transfer property (a value indicating empirically the degree of the printed densities for the same ink feeding amount) and for the same print unit and for the same printing sheets,
may be used as the initial values for the parameters B, V, F, R. Namely, when one factor of the three factors influencing the parameters B, V, F, R has been changed, parameters in the cases where the other two factors are the same may be set the initial values for the parameters.
Practically, special color inks other than CMYK are problematic. Due to the variety of them, it is difficult to determine adequate initial values of parameters B, V, F, R, and due to the low frequency of their use, it is not expectable for the parameters to be updated enough. Therefore, it is practical to use just preceding parameters V, F, R resultant from a different species of ink for the special color ink. The ink transfer properties for special color inks are often already evaluated empirically. A special ink parameter s is defined as an empirical value indicating the degree of increase in the ink feeding amount dependent upon the species of the ink, s=1 indicates a standard value, and it is assumed that, the larger the values of s, the larger the ink feeding amount is. A special ink parameters for a new special color ink and a special color ink parameter for another ink which was used just before are used. For instance, the basic parameter just before the ink change is referred to as B, the special ink parameter before the ink change is s′, and the special ink parameter for the new special color ink is s, and s/s′×B may be used as the initial value of the basic parameter B for the new special color ink.
Number | Date | Country | Kind |
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2016-150993 | Aug 2016 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2017/022038 | 6/15/2017 | WO | 00 |