EP0143228A1 - Method and apparatus for controlling the regulating means of the colour zones of an ink supply - Google Patents

Abstract

In the method, in which the colour distribution on an original (3) is sensed zone by zone and manipulated variables assigned to the regulating means or final control elements are formed, a high variability and operator convenience can be achieved by an arrangement in which the original (3) is transmitted onto a two-dimensional matrix (9) by light-activatable sensors (8), the number of sensors (8) thereby activated per colour zone is sensed and the manipulated variables assigned to the corresponding colour zones are formed from the sum of sensors (8) activated in each case per colour zone. This virtually accomplishes a digitising of the original. <IMAGE>

Description

According to a first idea of the invention, the invention relates to a remote mode for setting, in particular for presetting, the metering elements assigned to the ink zones of an inking unit or the actuators assigned to them, preferably designed as zone screws, in which the color distribution is recorded zone by zone on a template and from this the metering elements or respectively are assigned to these assigned actuators, and goes according to a further inventive idea on a preferred device for performing this method.

In known arrangements of this type (German printer 1974, pages 12-15), an assembly sheet is clamped onto a rotating drum which is illuminated from the inside. The light that penetrates this while the drum is rotating is collected by a series of fiber optics, the width of which corresponds to the width of the color zone. The amount of light per fiber optic, i.e. So per color zone, is integrated over a full revolution of the drum. The manipulated variable assigned to the associated color zone is then formed from this integral integral with the required amount of color. Here, a certain automation of the presetting of the zone screws is possible. However, it is disadvantageous that arrangements of this type are practically not variable with regard to the color zone width. A change in the color zone width would require changes in the design of the fiber optics and the integration devices assigned to them, that is, changes in the area of the so-called hardware, which required a great deal of time and capital. The known arrangements therefore prove to be not simple and variable enough. Another disadvantage is that skewing the template leads to incorrect information. A high effort must therefore be made to align the template and the drum, which can have a negative impact on the ease of use.

Proceeding from this, it is therefore the object of the present invention to increase the variability and user-friendliness of methods and devices of the type mentioned at the beginning.

The procedural solution to this problem is, according to the invention, that the template is transferred to a surface matrix of sensors that can be activated by light, that the sensors activated per color zone are recorded in number and that from the sum of the sensors activated per color zone, the associated color zones assigned manipulated variables are formed. For this purpose, a transfer device assigned to a receiving device for the template can be provided, through which an image plate designed as a surface matrix of light-sensitive sensors can be acted upon, followed by an interrogation device, by means of which the number of sensors activated within predeterminable color zone limits can be detected and the respective associated actuator can be controlled is.

The measures according to the invention advantageously lead to digitization of the template. The coarse screen image of the template that arises on the surface matrix can therefore be evaluated by software, which advantageously allows easy evaluation according to various aspects and results in a high degree of variability. A change in the width of the ink zone advantageously only requires a change in the program, i. H. the software, but not the system, d. H. the hardware. The advantages that can be achieved with the invention can therefore be seen in particular in excellent economy. The template is not moved here during the exposure of the area matrix. The zone alignment can therefore be easily carried out on the basis of the image edges, which ensures a high level of user-friendliness.

A frequency-selective transfer of the template to the surface matrix can advantageously take place. For this purpose, the transmission device can be provided with a switchable or exchangeable frequency filter. This ensures that a multi-color template can be used in the case of multi-color printing.

A further expedient measure can consist in that the coarse screen image that is created when the area matrix is acted upon is transferred to a screen, which is possible in a simple manner due to the digitization that has taken place. This measure allows a visual check of the coarse screen image on the screen and a visual comparison of the coarse screen image with the template and with the actuating variables determined therefrom, which can also be made visible in the form of analog variables.

A further expedient further development of the superordinate measures can consist in the sensors of the surface matrix being designed as photodiodes. These are practically optoelectric converters, each of which emit a current corresponding to the incidence of light, which enables simple addition of the signals emitted by several sensors by means of simple parallel connections.

Another expedient measure can be that the surface matrix has sensor rows running parallel to the color zone boundaries. This enables the sensors to be clearly assigned to the different color zones.

Further advantageous refinements and expedient further training of the superordinate measures result from the further subclaims.

The invention is explained in more detail below on the basis of a block diagram shown in the drawing of a device which is preferred for carrying out the method according to the invention.

The structure and mode of operation of printing presses and their inking units are known per se and therefore do not require any detailed explanation in the present context. As is known, the ink flow is adjusted by metering elements, such as scraper plates, ink take-up rollers, etc. The color flow is adapted to the respective requirements across the width of the inking unit. For this purpose, the working width of the machine is divided into several color zones each comprising a narrow strip, each of which is assigned an actuator approximately in the form of the zone screws 1 indicated in the drawing for the corresponding actuation of a metering element. The zone screws 1 are driven by respectively assigned actuators 2. To avoid waste when starting the machine, the zone screws 1 are preset before starting the machine. The required manipulated variable is determined on the basis of a template 3 corresponding to the print image to be produced.

In the present case, template 3 can be a positive template, for example in the form of an original or a slide. The template 3 is received on a holder, here in the form of a lighting table 4, with a suitable lighting direction is provided. In the case of an opaque original, this is applied with incident light, in the case of a slide with transmitted light. For illustration purposes, the color zones 5 resulting in the production of a print image corresponding to the original 3 in the printing press are entered in the area of the lighting table. To achieve a quick and reliable alignment of the template 3, the lighting table 4 is provided with a coordinate cross formed by stop bars 6. The ordinate of the coordinate cross runs parallel to the longitudinal extent of the color zones 5.

The holder formed by the lighting table 4 is assigned a transmission device 7, for example in the form of an electronic camera, through which the light emanating from the original 3 can be transmitted to an image plate, which is designed here as a carrier for a plurality of sensors 8 that can be activated by light, which are arranged in the form of a surface matrix 9 illustrated here by their grid lines. A sensor 8 should be arranged in the area of each intersection of the grid lines. When the transmission device 7 and the lighting device assigned to the lighting table 4 are activated, the sensors 8 of the surface matrix 9 practically draw a raster image of the template 3, which enables the template 3 to be digitized. The transmission device 7 is oriented with its optics 10 onto the template 3 in such a way that the edges of the template 3 are transferred to the corresponding edges of the surface matrix 9 and thus an exact covering is present.

The number of sensors 8 activated when light is applied to the surface matrix 9 within a surface unit of the surface matrix 9 corresponding to a color zone 5 and which practically forms a raster image of the template forms a digital dimension for the surface to be printed within the relevant color zone and thus for the area required within the relevant color zone Amount of paint. The number of sensors 8 activated within the strips of the surface matrix 9 corresponding to the color zones 5 is therefore detected and converted into corresponding actuating signals for the zone screws 1 or the motors 2 driving them. For this purpose, the area matrix 9 is followed by a query device 11.

The sensors 8 can simply be designed as photodiodes which emit a current when exposed to light. All sensors of the sensor rows running parallel to the color zone boundaries can be connected in parallel, as a result of which the currents emitted by the individual sensors 8 are added in a simple manner. In cases of this type, it is therefore sufficient if a query channel 12 leading to the query device 11 is provided for each sensor row. In some cases, however, it may prove expedient to query each individual sensor individually. In cases of this type, each sensor 8 is provided with a query channel connected to the query device 11. The values obtained by the interrogation unit 11 and corresponding to the number of sensors 8 activated per row or, in the case of individual interrogation, to the operating state of the respective interrogated sensor 8 are fed into an addition device 13 arranged downstream of the interrogation device 11, which fed values added up until all sensor rows or individual sensors of a surface unit of the surface matrix 9 corresponding to a color zone are queried. The resulting sum signal, which corresponds to the number of sensors 8 activated per color zone, is given to a downstream converter 14, which converts the given sum signal into a control signal, by means of which the actuator assigned to the color zone corresponding to the queried area unit of the area matrix 9 or to the latter assigned actuator 2 is controllable.

A pre-programmable microcomputer 15 is provided for the central control of the transmission device 7, the interrogation device 11, the addition device 13 and the converter 14. The ink zone width can be programmed here. A change in the color zone width therefore only requires a change in the program to be processed by the microcomputer 15. In the case of multi-color printing, a frequency filter 16 that can be set to the frequencies of the colors involved in the printing is provided in the area of the transmission device 7, so that a separate raster image can be generated on the surface matrix 9 for each color. The control of the frequency filter 16 and the corresponding activation of the outputs of the converter 14 leading to the zone screws of the individual inking units is also expediently carried out with the aid of the microcomputer 15 forming a central control unit. The example on which the drawing is based assumes four ink zones per inking unit. The converter 14 accordingly has four control outputs per inking unit, of which, for reasons of clarity, only the control outputs belonging to an inking unit and one indicates all other control outputs clearing control output are shown. The number of available ink zones depends on the machine width and the respective print image and can therefore vary. If the number of ink zones is reduced compared to the number of existing zone screws, several zone screws can simply be assigned to a common ink zone and controlled in parallel.

For visual control of the manipulated variables obtained by digital evaluation of the raster image that can be generated on the surface matrix 9, these can be transmitted in analog form to a screen 17 together with the raster image. This transmission can take place by radio. In the exemplary embodiment shown, suitable transmission cables leading from the screen 17 to the transmission device 7 or to the converter 14 are provided for this purpose.

The above explanations relate to the presetting of the zone screws 1. A continuous regulation of the zone screws 1 can take place with the aid of a target / actual value comparison, the raster image that can be generated with the help of an original template on the surface matrix 9 being the target value and that taken from the current production The raster image that can be generated on the surface matrix 9 forms the actual value.

Claims (10)

1. Method for setting, in particular pre-setting, the metering elements assigned to the ink zones of an inking unit or the actuators assigned to them, preferably designed as zone screws, in which the color distribution is recorded zone by zone on a template and from this the metering elements or the actuating elements assigned to them are formed are characterized in that the template is transferred to a surface matrix of sensors that can be activated by light, that the sensors activated per color zone are recorded numerically and that the manipulated variables assigned to the respectively associated color zones are formed from the sum of the sensors activated per color zone. 2. The method according to claim 1, characterized by a frequency-selective transmission of the template to the area matrix. 3. The method according to any one of the preceding claims, characterized in that the Beaufschla The area matrix on this resulting raster image is transferred to a screen. 4. The method according to claim 3, characterized in that the manipulated variables determined from the raster image are displayed in the form of analog variables, preferably transmitted together with the raster image to a screen. 5. Device for performing the method according to one of the preceding claims, by a holding device (4) for the template (3) associated with the transmission device (7), through which an image plate designed as a surface matrix (9) of light-sensitive sensors can be acted upon, the one Interrogating device (11) is arranged downstream, by means of which the number of sensors (8) activated within predeterminable color zone boundaries can be detected and the respective associated actuator (1) can be controlled directly or indirectly. 6. The device according to claim 5, characterized in that the sensors (8) arranged preferably in the form of sensor rows running parallel to the color zone boundaries are designed as optoelectric converters, preferably as photodiodes. 7. Device according to one of claims 5 to 6, characterized in that the interrogation device (11) is followed by an addition device (13) through which a downstream converter (14) can be controlled, by means of which the addition device (13) per color zone emitted sum signal can be converted into a control signal by means of which the actuator (1) of the associated color zone can be adjusted. 8. Device according to one of / claims 5 to 7, characterized in that the preferably designed as an electronic camera transmission device (7) is provided with a switchable or replaceable frequency filter (16). 9. Device according to one of claims 5 to 8, characterized by a with the area matrix (9) connected via a transmitting device screen (17) having g display. 10. The device according to one of claims 5 to 9, characterized by a central control unit forming, pre-programmable microcomputer (15) for controlling all device modules.

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