FI78355C - METHOD FOER MAETNING AV GLANS OCH APPARATUR FOER TILLAEMPNING AV METODEN. - Google Patents

Description

1 78355

METHOD OF MEASUREMENT OF GLOSS AND APPARATUS FOR THE APPLICATION OF THE METHOD - METHOD FOR MATERIAL AV GLANS AND APPARATUS FOR TILLÄMPNING AV METHOD

The invention relates to a method for measuring the gloss of a material to be produced as a web, such as paper, cardboard or the like, in which light rays emitted from a light source 5 placed on the other side of the material web, which are cut into parts, are passed to the material web. The invention further relates to an apparatus for applying the method.

Of the devices for measuring the gloss of paper and board, a 10 goniophotometer determines the reflection value of the light beam as a function of the measuring angle. The device can also be used to adjust the input angle. In the vicinity of the measuring angle corresponding to the angle of incidence of the light, a peak caused by mirror reflection can be observed. Measuring gloss with a goniometer is too cumbersome a routine method. In practice, gloss is measured with devices in which the angle of incidence and the angle of reflection are equal and are constant or adjustable to certain constant values. Measured from the normal of the surface to be examined, such angles are e.g. 20 ° and 75 °. 20 The gloss of the sample is determined in relation to the measured • reflected light and the conditions of the ideal mirror: the measured reflected light.

There are 25 problems with the above methods and devices. When determining one light incident angle and one measurement angle at a time, the physical fact is taken into account that when measuring a sample that is not close to the ideal mirror, it reflects the reflected light from both the mirror reflection and the scattered light. The scattered light is larger the closer to the idea-meat scatterer the surface to be examined and the smaller the angle used to measure the 2 78355 gloss. For this reason, in the case of low-gloss samples, the gloss is measured in practice at a very large measuring angle11a.

5 When measuring gloss from one measurement angle at a time, and especially when the measurement angle is large, the test sample must be in exactly the right place and position so that the measurement result is not incorrect. Even a small change in the position or setting angle of the sample relative to the measuring device 10 is sufficient to move the position of the reflected light beam in the measuring optics and to give an erroneous measurement result. The method is thus almost exclusively suitable for use in laboratory conditions. Under factory conditions, on-line measurement is: 15 very difficult or impossible due to its precise measurement geometry requirements. On-line conditions for measurement; van web "flutter", wrinkling, ripple, dust and dirt, difficult calibration and device instability cause poor measurement results as well as poor accuracy and reproducibility.

The object of the invention is to provide a method for measuring gloss which eliminates the drawbacks associated with current methods. The method 25 of the invention can be used to measure gloss under both laboratory and factory conditions as an on-line measurement.

It is a further object of the invention to provide a method and apparatus for measuring gloss which: utilizing gloss can be measured from both unpolished and high gloss products by the same method, apparatus and calibration. The equipment performs its standardization automatically and when measuring, the gloss result is obtained quickly and automatically.

The object of the invention is achieved by a method and an apparatus which are mainly characterized by what is stated in the claims.

Il 3 78355

According to the invention, the visible light is introduced to the surface after the light dividing device down to the optical fibers. The light is reflected on the surface to be examined radially to the same point in a plane 5 perpendicular to the surface to be measured, from several angles simultaneously. Gloss is measured with a photodetector device that is geometrically at the same level as the light rays coming on the surface to be examined. The photodetector device consists of photodetectors 10 set radially from a gloss measurement point to a quarter of a circular arc. An arc diffuser is placed in front of the light detectors,. which smooths out the vision of individual light detectors; light. In a plane perpendicular to both the surface to be examined and the plane reflecting and glossing light, light-detecting devices measuring stray light are arranged. Scattered light is measured on both sides of the gloss measuring plane by two detector devices which are similar to the gloss detector 20.

With the device according to the invention, the signals of the gloss-detecting detector and the scattered-light detector are computationally proportionally equal to a factor obtained from the non-glare of these detectors by the ratio of the ideal diffuser: measured responses. As a non-gloss ideal dispersant, a sample made of MgO 2 powder with a flat surface can be used. 30 Since, according to cosine law, the brightness of an ideally scattering surface does not depend on the angle of view, the gloss of such a surface is zero, so that the brightness of the test surface seen by the gloss detector is the same and the responses thus obtained must be 35.

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When measuring gloss, a luminous flux consisting of both the surface reflection component and the stray light components of the surface to be examined is obtained from the surface to be examined, and a luminous flux consisting only of the stray light component is obtained. The gloss is obtained by calculating the percentage of the mirror reflection component from the signal of the gloss detector by using the measured value of the stray light component.

10

When using the method and apparatus according to the invention, it may be permitted to examine in a measurement situation; movement of the surface with certain restrictions opt to the suction position - without still causing the measurement result too! 15 major mistakes. If the surface to be measured is inclined in any direction in the direction of the gloss measurement plane, this will cause the position of the reflected light to shift with the glare detector due to mirror reflection, The measured component of the stray light also remains the same because: its magnitude does not depend on the viewing angle. If again . the surface to be measured tilts in one direction in the direction of the diffuse light measuring device, the situation with respect to reflection and also in the measurement of stray reflection even if the brightness of the surface seen by the second detecting device decreases, compensates accordingly the total measurement result remains the same. In addition, the stray light component is the same in all directions. The displacement of the surface to be measured from one optimal position to another within certain limits also causes a very small error, as it causes the displacement of the mirror reflection components by the gloss detection system, but due to the structural solution of the detector system, no signal is lost. Scattered reflection measurement result

II

also remains unchanged. The gloss result therefore remains unchanged.

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The invention will now be described in more detail with reference to the accompanying drawing, in which Fig. 1 shows an apparatus for applying the method according to the invention schematically, Fig. 2 shows the sensor part of the apparatus according to Fig. 1 in three dimensions; Fig. 3 shows a transducer of the sensor part of the apparatus according to the invention. "Fig. A shows a cross-section and side view of an embodiment of the light-emitting part of the sensor • f of the apparatus according to the invention, and Fig. 5 shows a side view of an embodiment of the sensor part of the apparatus according to the invention.

Fig. 1 schematically shows a gloss measuring apparatus according to the invention, in which 1 is a surface from which gloss is measured. The light source includes lamp 2, mirror 3 and; a lens A for concentrating the radiation into a light splitter, i.e. a chopper 5. The apparatus further comprises: a filter 6 which modifies the light meter to suit the spectral response. From the filter, the light is directed forward in this application by means of an optical fiber bundle 7. Chopper! is arranged to break the light into parts in a known manner. by means of a rotating perforated plate, oscillation of a certain frequency, oscillating slits, etc.

The sensor part includes a light-bringing part 8, to which light can be introduced, for example, by means of known solutions of optical fibers, mirrors, light lamps or the like. The light beams 35 are arranged to focus radially on the measuring point through the aperture holes 10. The sensor part also includes two light detection devices 9, 13 mounted 6 78355 crosswise so that they are as if on the surface of a hemisphere. In this application, the light detection devices are arranged mainly at an angle of 90 ° to each other, but in other applications other solutions can be used. The intersecting plane of the hemisphere is the surface of the sample and the light rays are aligned on the surface of the web of material at the center of the hemisphere. In some applications, the sensor part includes more than two lighting and light detection devices. The photodetectors 12 are arranged in the photodetector devices 9, 13.

Figure 2 shows a three-dimensional preferred embodiment of the sensor part of the invention: The light rays are reflected from the surface 1 to be examined as a mirror reflection and as a diffuse reflection to a glare measuring device 9 and as a diffuse reflection only to a light detector device 13.

Fig. 3 shows a preferred embodiment of the light measuring device of the sensor-20 part according to the invention, which is preferably similar to the light detector device 9 measuring the gloss of Fig. 2 and the light detector devices 13a, 13b measuring diffuse light. The light detectors 12 are • placed radially on a quarter of a circular arc.

. 25 In front of the light detectors there is a light diffuser 11, as a result of which the light coming is evenly scattered to the light detectors.

Figure 4 shows a preferred way of illuminating the surface 1 to be examined according to the invention. The light is introduced by optical fiber cables 7 consisting of one or more optical fibers to a part 8 where the light is focused radially to the measuring point of the surface 1 to be examined through aperture holes 10.

Figure 5 shows a method according to the invention for arranging the illumination of the surface to be examined and the photodetector apparatus measuring the gloss. In the figure, however, the photodetectors 12 are interleaved with the light-producing fibers 7 in such a way that the photodetectors can see only the light reflected from the surface to be examined.

The light-seeing fibers between the light detectors are preferably prevented from seeing by the light tubes 14, one end of which forms an aperture hole 10 delimiting the light. The light tubes 14 are opaque to light. With the device according to Fig. 5, the gloss can be measured simultaneously from two opposite directions, and in this case too, the light detector device according to Fig. 5 can be used for measuring stray light, which is arranged so that it cannot see light in the mirror reflection.

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In another embodiment of the invention, the gloss measuring sensor part is constructed of two or more devices according to Fig. 5 by mounting them at an angle so that they come on the surface of the hemisphere, the cutting plane of the hemisphere being the plane of the sample and the light beams of the measuring apparatus are centered on the hemisphere. on the surface of the sample. The gloss is preferably measured by optically limiting the input of light to one of the apparatus of Figure 5 at a time, thereby measuring the sum of the mirror-reflection component and the scattered component of the sample in that direction. The scattered light component alone can be measured simultaneously with some other apparatus according to Figure 5, which is in such a direction that it is geometrically impossible to see the mirror reflection. Since in this sensor solution each of the apparatus according to Fig. 5 forming it is able to measure both the mirror reflection and the scattered reflection only, the gloss of the sample according to Fig. 5 used for the measurement can be measured by alternating the gloss of the sample from several directions. An optical shutter or similar device can be used for the alternation, with which light 8 78355 is allowed to enter only one device according to Figure 5 at a time.

One embodiment of the invention is a gloss meter constructed from the devices of Figures 3 and A Lai and Figure 5, in which light is brought to the surface to be examined alternately from one angle of incidence at a time and mirror reflectance is measured by one or more reflectors at the angle of incidence. with the detector by performing the measurement with one detector at a time. The measurement results can either be summed from both the entry angles and the measurement angles or processed individually as a function of the entry angle and / or as a function of the measurement angle, giving a goniophotometric image of the surface to be measured.

The invention is not limited to the preferred embodiments presented above, but many modifications are possible within the scope of the inventive idea defined by the following claims.

Claims (6)

A method for measuring the gloss of materials produced in the form of pulp web, in particular paper, cardboard or the like, in which method in a device placed on one side of the material web (1), from the light source (2, 3) , 4) suitable light emitted to its spectral properties, cut into pieces by means of a light distribution instrument (5) and guided on the material web, and for the determination of the gloss, the light reflection component of the light reflected from the material web is measured by a light detector (12). 10, which is at a mirror reflection angle, and the component of the diffuse light is measured with another light detector (13) from such an angle, where seeing of the mirror reflection is geometrically impossible, characterized in that the light is led on the surface of the material web (1). several angles of attack radially simultaneously in a piano, which is at an angle to the piano to be examined, and that for the determination of the gloss, from the material web, the sum of the mirror reflection component of the light is measured. and noise reflection component with the aid of a light detector device (9) consisting of several light detectors (12) which are in the same path with the light beams coming onto the material path and from the material path the noise reflection component is measured with the aid of another one of many light detectors 13 (1). such angle, seeing the reflection of the mirror reflection is geometrically impossible. Method according to claim 1, characterized in that the light is led on the surface of the material web from several angles of attack radially and simultaneously, that the lighting system forms half of a circular beam from whose circular circumference is radially illuminated the center point of the circumference and that the 1 detectors are located. alternate between the illumination points and are mounted optically so that they only observe the light reflected from the surface of the material web. Il i3 78355 3. A method according to claim 1 or 2, characterized in that the light is led onto the surface to be examined in the form of an extremely narrow beam of light and the illumination is distributed on short pulses, whereby for determination the brightness is reflected in the light reflected from the test piece for the time of each pulse separately. Method according to any one of claims 1-3, characterized in that the material web is illuminated with at least two different lighting devices and the direction of measurement of the gloss is selected by illuminating the material web with a lighting device at a time and by measuring it. the sum of the mirror reflection and diffuse light component with a light detector device, which is in the same pane with the illumination device, since the illumination devices in the other pane are closed and the light detector devices in these pipes measure the diffuse light reflected from the web. Device system for applying method according to claim 1 to which device system includes a light source (2, 3, 4) located on one side of the material web (1), a light distribution instrument (5), a filter (6) for filtering the light for its spectral properties suitable, means (7, 8) for guiding the partially cut light onto the material web, a gloss angle light detector device (9) for measuring the mirror reflection component of the light and such angle, from which view of the reflection of the reflection is impossible, positioned light detector device 30 (13) for measuring the component of the diffuse light, characterized in that the light is arranged to be passed through the light-carrying part (8) on the surface of the material web from multiple angles of attack radially in a beam which is at an angle in relation to the material web and that a light detector device (9) is placed in the same piano with the light beams arriving on the material web and to a light detector device one hears several light detectors (12) for measuring the sum of the mirror reflection component and for the diffuse light