DE102008027548A1 - Pattern kit for estimating ultraviolet portion of light source, has pair of calibrating patterns, where former pattern has quantity of colorant and quantity of fluorescent brightener - Google Patents

Abstract

The pattern kit has a pair of calibrating patterns. The former pattern has a quantity of colorant and a quantity of fluorescent brightener. The latter pattern has another quantity of colorant and another quantity of fluorescent brightener. The quantities of the colorant and fluorescent brightener are adjusted in the two patterns, such that two of the patterns convey the same impression under predetermined illumination conditions, when they are visual or assessed by a measurement, and a different impression in the other illumination conditions. An independent claim is included for a device for estimating the ultraviolet portion of a light source.

Description

The The invention relates to a pattern set for estimating the UV component (ultraviolet light) of a light source or certain Lighting conditions.

In the printing industry uses fluorescent whitening agents (FWA), to improve the visual quality of the printed image. The FWA brighten the colors, drown out the natural Yellowing of the print media, improve the source color and the Brilliance of colored or black pigmented articles. Obviously the effect of FWA depends on the proportion of fluorescent (Ultraviolet) radiation of the illuminating light source. The visual picture of the pressure varies depending on the Intensity and wavelength of ultraviolet light and of course depends on the one used Active ingredient and its characteristic properties. Since that printed picture for consideration at a certain, predetermined illumination can be determined, for example, in bright Daylight or in different, artificially lit Spaces, it is important that the amount and type of FWA can be set correctly. For this purpose, the printed Image or unprinted paper under standardized lighting conditions be evaluated in order to be able to adjust the printing process, that a picture with the desired properties in the Viewing environment in which it is to be viewed can.

A Display or measurement of intensity and wavelength UV light is also used by the lighting industry needed for quality control, for example. It is also conceivable that a UV measurement may be harmful for the determination Quantities of UV light, for example in sunlight or an electric Welding arc is used.

It It is known that the UV component of a lighting source often is unknown, although standardized lighting conditions are available, such as in a printing room. It was determined, that fluorescent paper samples under variable Be examined light sources. Depending on the UV component of the illumination or light source show fluorescent paper samples changeable shades. It was further stated that in a color management environment light sources in the visible Spectrum and are defined in terms of UV fraction. It is but still difficult to control the UV fraction. Usually requires the estimation of the UV content of a light source complicated and expensive measuring devices.

From the European Patent Application 0 744 191 A2 is a measuring sheet for ultraviolet light known. The UV light sheet has a sheet base and a photochromic layer that changes color as a function of the intensity of the ultraviolet light. The reference UV reference sheet allows a user to judge whether the UV intensity is sufficient for tanning or not by comparing the color of the UV sensitive part with the reference colors of the UV dial. In use, the user places the measurement sheets in the vicinity of fluorescent tubes of a tanning apparatus to thereby irradiate the photochromic layer with UV light. Upon irradiation, the photochromic layer changes color within a few minutes depending on the intensity of the ultraviolet light. The color density of the photochromic layer is compared with the density of the colored part with the reference colors.

JP 11 101 687 A discloses an apparatus for measuring the radiation intensity of ultraviolet rays in solar radiation in preparing a manuscript sheet for a printing plate. The device has a radiation intensity sensitive portion of a photochromic layer whose color density varies in proportion to the radiation dose of the ultraviolet rays per unit area. It further has a plurality of color density reference areas adjacent to the radiation sensitive portion, and corresponding guide display areas on a single paper sheet. When the paper sheet of the radiation intensity measuring apparatus is exposed to solar radiation, the density of the colored radiation-sensitive portion is compared with the plurality of color density reference ranges, and the areas of the same density are selected by optical inspection. Then the manuscript sheet can be prepared.

From the JP 2003138499 It is known to provide a colored paper for easy measurement of the amount of light having a given color fade factor for a given amount of light which is highly reproducible and enables a visual assessment of color fading depending on the amount of light from a light source. The paper is a blue test paper that measures the amount of ultraviolet light emitted by the fluorescent tubes by visually distinguishing fading. The paper is obtained by preparing a printing paper of 50 weight percent L-BKP and 50 weight percent N-BKP, with 0.5 weight percent CI Acid Blue 90 and CI Direct Blue 203 respectively used in papermaking.

US 2002/0039181 A discloses a method and apparatus for controlling a dyeing pro in which at least one fluorescent or non-fluorescent ingredient is added and the color of the substrate is determined by the use of a color model describing the effect of the ingredient on the radiance transfer factor of the substrate to be inked. The color is controlled by the amount of ingredient added during the dyeing process. The task of color control is to minimize specified color errors by controlling the available dose of ingredients. The color control is based on a color model containing parameters of the ratio of the absorption coefficient differential to the amount of the fluorescent ingredient to be added, the ratio of the scattering coefficient differential to the amount of the fluorescent ingredient to be added, and the ratio of the fluorescent coefficient differential to the amount of the fluorescent ingredient to be added. Because a majority of the total radiance transmit factors correspond to the same sensed color, the color model generates the ratio of the change in an optimized radiance factor to the amount of the fluorescent ingredient based on process state measurement data and parameters that may or may not be dependent on the process state. The total radiant density transmission factor relative to the amount of fluorescent ingredient can be determined under different illumination conditions that allow the substrate to be colored to be provided with the desired illumination metamerism when spectral radiance of samples under one illumination source match, but not below one another. The total transmission factor contains a fluorescence extension for the Kubelka-Munk theory. Instead of the radiation density transmission factor, the model can provide an apparent reflectance or a true reflectance.

Other documents consider the measurement of paper whiteness, such as Color Research and Application, Vol. 19, No. 6, December 1994, J. Anthony Bristow "The calibration of instruments for the measurement of paper whiteness" , This document describes that the so-called ISO brightness is defined as a filter function or mathematical function with an effective wavelength of 457 nm and a half width of 44 nm. This filter with a maximum transmittance in the blue range was selected for process control in the pulp industry because of its sensitivity to changes during pulping of pulp for papermaking. It is further noted that the correct method for achieving absolute calibration in the presence of fluorescent materials is the use of a double monochromator system with a 45 "0 ° geometry. At each step, the monochromator on the output side allows analysis of the radiated energy on the one hand in radiation reflected at the input wavelength and on the other in radiation emitted at other wavelengths in response to the absorption of lower wavelength energy by the fluorescent substance ,

Farther Ugra announces a light indicator and a metamerism card. The Ugra light indicator is for optical inspection the color temperature of lighting equipment in color determinations used. For this purpose, a Ugra light indicator on the edge of a Trial proof attached. There he signals whether the lighting used the standard color temperature of 5000 K under a standard light imitated by D50. If a default color temperature of 5000 K is used, The spots of the Ugra light indicator appear in the same green Colour. If the color temperature deviates from 5000 K, the show Patches of Ugra light indicator different colors. The indicator strips have a releasable adhesive on their back on, leaving them on the verge of proofs, printing or Other objects can be fixed under one Standard lighting of 5000 K should be considered. The Ugra Metamerism card has a size of DIN A5 on and will be for the final inspection of the lighting used and has the same function as the Ugra light indicator on.

Furthermore, some international standards have been introduced, such as ISO 11475, first edition 1999-03-01, "Paper and board - Determination of CIE whiteness, D65 / 10 ° (outdoor daylight)" . ISO 2470, third edition 1999-10-15, "Paper board and pulps - Measurement of diffuse reflectance factor (ISO brightness)" . ISO 11476 "Paper and board - Determination of CIE whiteness, C / 2 ° (indoor is illumination conditions)" , The latter cited international standard specifies the method to be used for determining the whiteness of papers and cardboards to obtain values corresponding to the visual impression of white paper and white cardboard, with or without fluorescent brighteners, when viewed indoors. It is based on remission grade data collected over the entire visible spectral range, in contrast to the measurement of ISO brightness, which is limited to the blue region of the visible spectral range. This International Standard further specifies a method of adjusting the UV content to correspond to CIE illumination C, since the results obtained when fluorescent brighteners are present are dependent on the UV content of the radiation impinging on the sample. The CIE light source C is considered to be representative of indoor lighting since it has a suitable proportion of UV radiation. The However, this method is not applicable to colored papers with fluorescent dyes; it is only specific in the situation where fluorescence occurs in the blue region of the visible spectrum.

The above international Standard ISO 11475 specifies the method for obtaining values corresponding to the appearance of papers viewed under the CIE light source D65 (daylight outside). The method corresponds to the method according to ISO 11476 in which the method is specified to adjust the UV content of the D65 daylight source to the extent that results obtained when fluorescent brighteners are present are dependent on the UV content of the radiation incident on the sample. This method is specific for the measurement of fluorescence in the blue region of the spectrum and is not applicable to colored papers with fluorescent dyes. This international standard should be related to ISO 2469 be read as mentioned above. This international standard specifies a method for measuring the diffuse blue reflection factor (ISO brightness) of pulp, paper and board. This standard is limited to white and almost white pulps, papers and cardboard. A brightness value associated with a device setting tuned to the CIE standard light source D65 whose UV fraction is much larger than that of the CIE light source C is not the "ISO brightness" as they are in ISO 2470 is described. The method specified in this International Standard applies only to white papers containing 15 fluorescent brighteners whose fluorescence is in the blue region of the visible spectrum at 400 to 500 nm; however, this method is not applicable to correct adjustment of fluorescence in other spectral regions.

outgoing This is the object of the invention, a simple Way to estimate the UV content of a light source, the simple, easy to use and inexpensive Measuring device used.

According to one Aspect of the invention will achieve this object according to the present invention by a pattern set for estimating the UV content of a light source through the use of calibration patterns solved, the calibration pattern with different Combinations of dyes and amounts of fluorescent brighteners are provided. The calibration patterns are visually compared to determine if at least two patterns are visually identical or just below a certain UV component of a calibration light source are and look different among all other UV components. On In this way, the unknown UV component of a light source can be determined become.

According to one In another aspect of the invention, the object is also achieved with a device solved in which a series of calibration patterns with different Combinations of dyes and amounts of fluorescent brighteners are provided, wherein at least two of them visually identical table or are just below a certain UV component of the light source and visually different under all other lighting conditions.

Further Embodiments of the present invention will become apparent from the dependent claims.

The The present invention thus provides a simple way of estimation of the UV component of a light source by visual comparison of patterns such as Calibration cards containing different combinations of dyes and amounts of fluorescent brightener are treated. With the Apparatus and the method according to the present invention Application, it is now possible to reduce the UV content under lighting conditions to control, usually only for several Standard lighting is defined and not even by the Manufacturers of lamps are ensured that use these light sources to offer. The usually occurring differences in the Measuring, visually judging and being in process control now by the use of the method and the device according to the overcome the present invention. With the device and the method according to the present invention is a simple method for estimating the UV content or Part of its spectrum for the printing and paper industry provided. By using the device according to the present invention is the cost of measuring the UV component low and the meter is neither expensive nor complicated. Especially in the paper and printing industry there is a need for measuring and estimating the UV component of the lighting environment. This can now be done easily by using the method and the device according to the present invention respectively. If the UV lighting conditions can be displayed, is it possible to set the printing more precisely, so that a desired visual character of the printed Surface is reached. In this way, the invention provides an excellent and relatively inexpensive tool to estimate the final quality of the product and an aid to planning the overall impression of the printing work.

in the Below, the invention with reference to the accompanying drawings explained in more detail:

1 shows the principle of the invention.

2 is a diagram of the design principle of the invention.

The Patterns are created for visual examination. The comparison between the patterns can be done by a person or by an electronic device or machine capable of is to determine whether two patterns or at least two patterns one have the same shade under a certain UV component or not. A calculation of the amount of fluorescent brightener and dyes is in the device for estimation the relative UV component of a light source in different Combinations implemented in a series of patterns or calibration patterns. By a visual examination or examination of a visual Investigation machine is then possible find a pair of calibration patterns or test fields by the series of patterns is compared visually. The comparison is through a determination is made if two patterns are identical or equal to a certain amount of UV light in the lighting are or not. All other test fields of the patterns should have different shades exhibit.

The Patterns are made by fluorescent brightener and dye applied in different amounts and relative proportions on paper become. In principle, any fluorescent whitener can be used as well as any dye that activates through the FWA responding. A dye that can be used is yellow dye, For example, a dye called levacell yellow. To the patterns different combinations of FWA and Dye applied to paper and thus prepared samples can be done by visual inspection or by measurement the b-values between the patterns are evaluated. The b-value is a value determined by the CIEL * a * b * color system, where L * is black-and-white, a * red-green and b * represents yellow-blue. Thus, when using yellow dye The b value can be effective for distinguishing between the patterns be used. However, it must also be noted that the patterns must also be distinguishable by visual comparison, if it is intended for use without special measuring equipment are. If patterns with a clear visual and / or measurable Difference under the specific conditions of the D65 light source can be chosen, such couples in large Quantities are prepared for the evaluation of UV irradiation conditions.

For each pair of samples, the amount of dye and FWA or their proportions are different. Therefore, each pair of patterns produces a different visual image under different lighting conditions. However, the patterns are matched so that, for a given amount or intensity of UV light, the patterns give a similar visual image, and preferably also the same B values within the boundaries, so that the patterns can be visualized or measured by B Value can be considered as showing the same image. In principle, the patterns can be made to display every percentage of UV light, however, patterns indicating 0%, 50% and 100% UV are most useful. The comparative percentages of illumination under the standard D65 light source are used for measurements after ISO 11475 is used. 0% UV means that the light source does not emit UV radiation when measuring the optical properties of paper (for example, L, a, b values, CIE whiteness, and so on). This is the case when papers are measured with a UV cut filter in the ELREPHO. (ELREPHO is a device for measuring brightness, whiteness, color, coverage and other optical parameters, and known in the paper industry). This means that the fluorescent brightener is not active. 100% UV means that the UV component of a light source is similar to the UV component used in standard measurements of optical properties. This corresponds to the lighting conditions on a sunny day. 50% UV content means that exposure to fluorescence is half the fluorescence value at 100% UV fraction [UV (D65)]. This assumes a linear approximation between the UV blocking values and the UV (D65) values.

The idea of the invention is to provide certain pairs that are visually equal only under certain UV conditions. 1 shows a map where three pairs (0%, 50% and 100%) are used for the UV component of the light source D65. If there is no UV in the tested light source, then the 0% pair of samples will look visually equal and the 50% and 100% sample pairs will be visually different. If the light source has a 50% UV content then the 50% pattern pair will look the same and the sample pairs 0% and 100% will be visually different. In the latter case, the 100% pattern pair will look the same and the others visually different if the D65 light source is 100% UV. The rating is done visually in this case. However, it is also possible to use different measuring apparatuses for evaluating the patterns. For example, the b-value may be measured as mentioned above or any other value concerning the visual impression of the pattern. The most obvious values are the L, a, b values, the CIE whiteness and other properties normally used in the paper and printing industry.

2 shows how the patterns can be designed for visual assessment. The Y-axis shows the reflectance in% and the X-axis the Wavelength in nanometers (nm). This figure shows the measurements of a pair of samples (A and B) designed to be the same under ideal conditions, in this case at 50% UV. The lowest (circles) and middle (squares) curves show the reflectance for the two patterns in the absence of UV (0% UV). In this case, pattern A and pattern B are clearly different and thus visually different in the absence of UV (0% UV). The reflection levels of the patterns are significantly different over a wide wavelength range. The upper curves show the same patterns in the case of 50% UV. The reflectance curves now coincide and the patterns appear immediately in this particular UV situation. Now the curves marked with squares and circles overlap at all measured wavelengths. In principle, the amount of UV could be 100% or any other percentage of UV to be tested or displayed.

According to one Embodiment of the present invention, it is possible To design patterns for just one specific UV situation for example, for the UV-C content. In this situation a comparison is made to determine if the light source has a UV-C content or deviates from it. Generally speaking becomes the method according to the present invention provided a specific predetermined UV fraction to determine a light source using calibration patterns which are the calibration patterns with different combinations of dyes and amounts of fluorescent brighteners. The determination of whether the light source has the predetermined UV component or deviates from it, by visual inspection of the calibration pattern and Selection of a specific calibration pattern for this specific, designed to be examined UV component performed. It has proved to be very advantageous that according to the present invention, each pair of calibration patterns under certain UV components of the light source is visually identical and different Shades under all other lighting conditions with different UV component has. Accordingly, in each case two of the calibration patterns visually identical under a specific, predetermined UV fraction of the Light source when a specific, predetermined UV component of a Light source to be determined.

It It is thus obvious that there are different applications of calibration patterns where the estimation of the UV component is a light source and another, the determination of a specific, predetermined one UV component a light source. There is thus a wide field of application which leads to the advantage that the described calibration patterns and methods for very different industrial or non-industrial applications can be used For example, in the paper and printing industry, the lighting industry etc.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - EP 0744191 A2 [0005]
• JP 11101687 A [0006]
• - JP 2003138499 [0007]
• - US 2002/0039181 A [0008]

Cited non-patent literature

• Color Research and Application, Vol. 19, No. 6, December 1994, J. Anthony Bristow, "The calibration of instruments for the measurement of paper whiteness" [0009]
• - ISO 11475, first edition 1999-03-01, "Paper and board - Determination of CIE whiteness, D65 / 10 ° (outdoor daylight)" [0011]
• - ISO 2470, third edition 1999-10-15, "Paper board and pulps - Measurement of diffuse reflectance factor (ISO brightness)" [0011]
• - ISO 11476 "Paper and board - Determination of CIE whiteness, C / 2 ° (indoor is illumination conditions)" [0011]
• - Standard ISO 11475 [0012]
• - ISO 11476 [0012]
• - ISO 2469 [0012]
• - ISO 2470 [0012]
• - ISO 11475 [0023]

Claims (6)

Sample set for estimating the UV component a light source, the set comprising at least a pair of calibration patterns characterized by - at least a first Pattern, with a first amount of dye and a first amount fluorescent brightener, - at least a second one Pattern, with a second amount of dye and a second amount fluorescent brightener, of which quantities at least one is different than at least one of the first quantities, and - in the quantities set in at least the first and second patterns Dye and fluorescent brightener that at least two the pattern under a predetermined lighting condition the same Convey impression, if at least visually or through a Measurement are judged, and a different impression other lighting conditions. Pattern set according to claim 1, characterized that at least two of the calibration patterns at a certain UV component the light source are visually identical and different in all other UV components. Pattern set according to claim 1 or 2, characterized that at least two of the calibration patterns at a certain UV component the light source have identical measurement results and different Results for all other UV components, if at least one L, a, b values, CIE whiteness or others in measured properties used in the paper and printing industry. Pattern set according to one of claims 1 to 3, characterized in that the set at least three pairs of patterns having. Pattern set according to claim 4, characterized that the set comprises at least three pairs of patterns, one of them 0% for couples, 50% for couples and 100% UV for couples indicating the lighting D65 light source. Apparatus for estimating the UV content of a Light source, wherein the device at least a pair calibration pattern characterized by - at least a first Pattern, with a first amount of dye and a first amount fluorescent brightener, - at least a second one Pattern, with a second amount of dye and a second amount fluorescent brightener, of which quantities at least one other than at least one of the first quantities, - in the quantities set in at least the first and second patterns Dye and fluorescent brightener that at least two the pattern at a predetermined illumination condition the same Have image when evaluated by a measurement, and a different picture under different lighting conditions, and A measuring device for determining at least one the CIELab values, where the L value stands for the brightness, the a-value for the green-red component and the b-value for the yellow-blue component, or the CIE white content.