DE3233453A1 - Apparatus for measuring the colour density of a colour control strip incidentally printed on a printed product - Google Patents

Abstract

An apparatus for measuring the colour density of a colour control strip incidentally printed on a printed product includes a light source (7), by which the printed product is illuminated. Diffusely reflected light passes via an optical system (13, 16) to at least two dichroic mirrors (18, 21), each of which reflects one of the primary colours, which produces white when combined with a complementary colour, against a photoelectric receiver (20, 22, 25) or allows it through. <IMAGE>

Description

Device for measuring the color density of a printed product

The invention relates to a Device for measuring a color control strip printed on a printed product, which contains at least three color measuring fields and is illuminated by a light source, wherein remitted or transmitted light is fed to a photodetector arrangement will.

Such a device is already known (DE-OS 22 53 189). A paper web provided with the color control bar is used in this device deflected by a cylinder. The alignment on the cylinder over which the Test pattern moved, is illuminated by a light source. The reflected light falls to a photoelectric receiver. In the beam path of the reflected light a color filter wheel is arranged. The output of the photoelectric receiver is amplified and then fed into three channels, which facilities for synchronizing the color filter wheel for determining the color density and for focusing the optical receiver are connected downstream.

The invention is based on the object of providing a device of the initially described described genus in such a way that the measurement of the color density the individual color measuring fields can be done without a color filter wheel.

The object is achieved according to the invention in that in the beam path of at least two dichroic mirrors are arranged, of which each one of the primary colors, which is complemented by a complementary color to white, against a photoelectric receiver reflected or transmits.

With this arrangement, the effort for the drive and the Synchronization of a color filter wheel. Still you can use an optical system the color densities of different colors can be measured. Small, Record adjacent color measuring fields one after the other. Particularly claimed the device takes up little space. You can therefore with little effort along the color control bar on rotary printing machines via the color measuring fields corresponding to the different color zones be moved. Dichroic mirrors can also be used for which one of the primary colors, which is complemented by a complementary color to white, is allowed to pass through while the rest of the colors are reflected. In this case it is let through Light directed at a photoelectric receiver while the reflected Light reaches the downstream dichroic mirror.

Preferably that is transmitted by the second dichroic mirror Light directed at a third photoelectric receiver. With this arrangement a dichroic mirror can be saved. For measuring color measuring fields two dichroic mirrors are sufficient for white, black, cyan, magenta and yellow the end.

In a preferred embodiment it is provided that the from second dichroic mirror transmitted light to a third photoelectric Recipient is directed.

Further advantageous refinements and developments of the above The measures explained are described in claims 4 to 9.

The invention is illustrated below with reference to a drawing Embodiment explained in more detail, from which further features and advantages result.

The drawing shows schematically an apparatus for measuring the Color density of a color control bar 2 which is also printed on a material web 1, which contains at least three color measuring fields 3, 4, 5. The color measuring fields 3, 4 and 5 are each intended for different colors.

The color density of the colors present on the color measuring fields is determined with a measuring head 6 in which a light source 7 is arranged, the one Ißpti 'd is preceded, which generates an approximately parallel light beam. Between the light source 7 and the optics 8 is a Warr, 1ew he 9. On dc the Lichtouei'e On the side of the optics 8, a diaphragm 10 is arranged which forms a light beam 11 fades out with a circular cross-section. The light beam 11 enters a dimming channel 12, at the end of which an exit optic 13 is arranged. Through the exit optics 13, a light spot is generated on the material web 1. The exit optics 13 are used at the same time as entrance optics for the light reflected from the material web 1. For the reflected light has the optics 13 a large opening angle.

The reflected light leaves the optics 13 as approximately parallel Light bundle 14 that arrives at a deflecting mirror 15 that surrounds the anti-glare channel 12. The light is deflected by the mirror 15 to an optic 16, which is a converging Light beam 17 is generated. In the beam path of the light bundle there is a first dichroic one Mirror 18 arranged, which is transparent to green and red light and blue Light reflects. The blue light reflected from the dichroic mirror 18 arrives via a narrow-band filter 19 to a first photoelectric receiver 20. The permeability of the filter 19 is in that range of the light wavelength matched, which is the color when mixed with the complementary color yellow white results.

After the first dichroic mirror 18 is a second dichroic mirror Mirror 21 arranged in the beam path of the light beam 17. The dichroic mirror 21 is transparent to red light and reflects green light to a second photoelectric receiver 22.

In the beam path of the reflected from the dichroic mirror 21 green Another filter 23 is located for green light within a certain area is permeable. The wavelength range is selected so that that the transmitted light when mixed with light that changes color magente that turns white.

The converging light beam 17 reaches the second dichroic one Mirror 21 via a narrow-band filter 24 to a third photoelectric Receiver 15. The filter is permeable to light of a certain wavelength range, the radiation of which, when mixed with light of the color cyan, results in the color white. Between the optics 16 and the first dichroic mirror is an infrared filter 26. The outputs of the photoelectric receivers 20, 22, 25 are connected to an amplifier and evaluation circuit connected, with which the reflectance or the density the color is determined. The degree of remission is defined as follows: ß = 0 F / X , where TZ1F is the remitted light of the color surface and W is the remitted light Light of the white background is. For the color density, D = log 1 Das am first applies Photoelectric receiver occurring signal is the reflectance of the yellow Color proportional. At the output of the second photoelectric receiver arises a signal proportional to the reflectance of the color magenta. At the exit of the third Photoelectric receiver 25 generates a signal that the reflectance of the Color is proportional to cyan. At the output of the second photoelectric receiver 22 there is also a signal proportional to the degree of remission black when a black color measuring field is scanned.

The outputs of the photoelectric receivers 20, 22, 25 are for example processed by logarithmic amplifiers with subsequent subtraction. The output signals of the photoelectric receivers 20, 22, 25 can also be digitized and then logarithmized in a computer and subtracted from each other.

In the drawing, optics that are not designated in detail are in each case the filters 19, 23, 24 arranged. With these optics, the differences are due to different paths of light from the scanning point to the photoelectric Recipients can occur balanced.

The further processing takes place in consideration of the Scanning a white, d. H. non-colored, zone of the web of material obtained Output signals. After forming the relationship between each when scanning of color measuring fields for cyan, magenta, black and yellow won Values and the value obtained by scanning a non-colored area the color density belonging to the respective color measuring field. Dichroic mirrors are also used in cameras. The dichroic mirrors used for cameras can also be used for the densitometer described above.

Claims (9)

Device for measuring the color density of a printed product with the color control bar printed with the patent claims G) Device for measuring the color density a color control bar printed on a printed product, the at least three Contains color measuring fields and is illuminated by a light source, with remitted or transmitted light is fed to a photodetector arrangement, thereby characterized in that in the beam path of the reflected or transmitted light at least two dichroic mirrors (18, 21) are arranged, each of which is one of the primary colors, which complement each other with a complementary color to white, against one photoelectric receiver (20, 22) reflects or transmits. 2. Apparatus according to claim 1, characterized in that the from second dichroic mirror (21) transmitted light to a third photoelectric Receiver (25) is directed. 3. Apparatus according to claim 1 or 2, characterized in that the first dichroic mirror (18) reflects the primary color blue and for the Primary colors green and red is transparent and that the second dichroic mirror (21) the primary color reflects green and is transparent to the primary color red. 4. Device according to claim 1 or one of the following claims, characterized in that in the beam path of the dichroic mirrors (18,21) reflected light each narrow-band filter for the passage of a the complementary color to white complementary wave range are arranged. 5. Device according to claim 1 or one of the following claims, characterized in that an infrared filter in front of the first dichroic mirror (18) (26) is arranged. 6. Device according to claim 1 or one of the following claims, characterized in that that occurs when a yellow color measuring field is scanned Output signal of the first photoelectric receiver (20) as an output variable for the determination of the color density of the color yellow is used. 7. Apparatus according to claim 1 or one ocr claims 2 to 5, characterized characterized in that that when scanning a magenta or black color measuring field occurring output signal of the second photoelectric receiver (22) as an output variable is used to determine the color density of the color magenta or black. 8. Apparatus according to claim 1 or one of claims 2 to 5, characterized characterized in that that occurs when scanning a cyan color measuring field Output signal of the third photoelectric receiver (25) as an output variable for the determination of the color density of the color cyan is used. 9. Device according to claim 1 or one of the following claims, characterized in that the three photoelectric receivers (20, 22, 25) with each signal occurring when scanning a white color measuring field the signals occurring with the respectively assigned color to the Determination of the color density is used.