DE8005193U1 - DEVICE FOR DETERMINING INDIVIDUAL COLOR COMPONENTS IN A MULTICOLOR PRINTING BY MEANS OF A DENSITOMETER - Google Patents

Description

The innovation relates to a device for determining individual color components in a multicolor print by means of a densitometer and color filters assigned to this, the coloring of which corresponds to the complementary colors of the individual printed colors is equivalent to.

Densitometers are used in the printing industry to monitor print quality for color density. For color measurement measuring fields printed on the sheet are either used or measurements are taken directly in the image, with a In contrast to measuring field measurements, direct measurements in the image are not pure standard printing inks, but mixed colors the standard printing inks. To the one created from the standard printing inks Mixed color is also printed black in four-color printing, so that there is room for the field of view of the densiometer results in a mixed color consisting of four individual components.

There is no densitometric measurement in the image that differs from a measured value on the sample sheet the possibility of the printer changing a color component directly based on the densitometer measurement. The problem This is due to the fact that when the three standard hues are printed together one already receives gray values to which there are still the directly printed black added. A measurement with a conclusion about the individual color components in a mixed color is therefore only possible in three-color overprint (see magazine "The Polygraph" 8/77). Accordingly, the currently used densitometer only to detect a color change in a color overprint or for measuring the individual colors on a measuring strip. A detection of the black component due to a "visual filter" for the Black measurement is not possible. This visual filter works in the same spectral range as the filters for capturing the Chromatic components and therefore does not provide an independent fourth measured value.

The task of the innovation is therefore to provide a measuring device, to create, with which the proportions of all colors in a four-color overprint can be determined. In particular it should be made possible that, after the measurement, the printer receives information about which color guide has been changed must become.

This task is solved by the label according to the protection claim 1 .

The inventor makes use of the knowledge that standard hues are transparent for printing in a certain spectral range (infrared), but this spectral range is absorbed by the fourth color component black.

A densitometer that meets the requirements is described below in terms of its structure and mode of operation: Compared to conventional densitometers, the densitometer has an infrared-compatible optics, one that is suitable for the infrared range Photo receiver and an infrared filter, which is arranged in place of the usual "visual filter" for measuring black is.

The procedure for measuring in a four-color overprint is as follows:

To determine the color, the densitometer is placed over the measuring field of the printed sheet, and it is used for a color overprint a measurement was made with all four filters to determine the four color components. The one from the four measurements The resulting measured values clearly identify a color that consists of three chromatic components and black.

There are now four independent measured values for four-color printing are, the individual amounts of color can be calculated or read from a color table: because every combination of measured values is clearly assigned to a color combination. (A color table can therefore be created by measuring sample sheets If there are color deviations, the

Printer can recognize the triggering color component directly and correct it on the respective inking unit.

The structure of the densitometer is as follows:

The densitometer itself differs in its construction from the known densitometers in that in one through a motor 4 rotatable filter wheel 2 in addition to the usual filters 8, 9, 10 and an infrared filter 11 in the The beam path of the measuring beam 1 is pivotable. The photodetector 3 must accordingly be selected so that the entire expected spectral range is detected. The output signals 5 emanating from the photodetector 3 are then passed through an electronic evaluation system 6 further processed.

A further embodiment of the densitometer can be made according to FIG. 2 as follows:

The measuring beam 1 reaches a first filter mirror 7 via an optical system 12, which is transparent to infrared light and red light is. Green and blue are directed through the first filter mirror 7 onto a further second filter mirror 7.1, which is permeable to green. The remaining blue portion is fed directly to a blue detector 3, Behind the second filter mirror 7.1 there is a ground detector 3.1 onto which the green portion of the measuring beam 1 is directed will. The infrared and red components of the measuring beam, which has passed through the first filter mirror 7, is through another third filter mirror 7.2 split into the red and infrared components and also corresponding Detectors 3.2, 3.3 supplied. The signals provided by the individual detectors 3 - 3.3 are then in a Electronics processed in a known manner. It would also be conceivable that individual photodetectors are used, which in are selective in a different spectral range. The corresponding filters could then be omitted. The measuring beam would then be fed via known optical beam trellis to the individual photo detectors.

Claims (4)

ROLAND Druckmaschinen Aktiengesellschaft Christian-Pleß-Strasse 6-30, 6050 Offenbach am Main Device for determining individual color components in a multi-color print using a densitometer. Protection claims 1.) Device for determining individual color components in a multicolor print by means of a spectrally sensitive measuring device, characterized in that that optical means (8, 9, 10, 11; 7, 7.1, 7.2) are provided through which a measuring beam (1) can be divided into four spectrally different partial beams that for detecting these partial beams one or more photodetectors (3) are provided, a partial beam in the infrared range and the assigned detector is suitable for measurement in the infrared range. 2.) Device according to claim 1, characterized in that the measuring beam (1) follows one another in time through the individual filters (8, 9, 10, 11) mounted on a filter wheel (2) to a photodetector (3) can be supplied, wherein the filter wheel (2) can be driven by a motor and the output signal (5) of the photodetector (3) can be fed to an electronic evaluation system (6). 3.) Device according to claim 1, characterized in that the measuring beam (1) has individual semi-permeable Filter mirror (7) can be fed to the individual photodetectors (3). 4.) Device according to claim 1 to 3, characterized in that the filter used for the infrared measurement or an infrared photodetector in the area of the
is impermeable or non-selective by the spectral range absorbed by water.