DE1193701B - Device for photoelectric error control of material surfaces - Google Patents

Description

Device for photoelectric error control of material surfaces The invention relates to a device for photoelectric error control of Material surfaces, In known devices of this type, the surface a web running over a scanning line or a sheet-like product, So about paper, plastic foils or metal foils, through a transverse to the direction of flow of the product scanned light beam, where U is the brightness of the Light beam on the scan line generated light spot on a photoelectric Converter, e.g. a photocell or a secondary electron multiplier, acts, and the voltages generated in this converter to indicate any errors to be used. With these devices it is important to use the photoelectric Converters to determine the deviations that arise when errors occur on the surface to be tested versus when scanning a defect-free surface given tensions.

The invention is based on the object of designing the device so that even if small errors occur, a reliable error display is made possible, whereby this purpose can be achieved with the least possible structural effort target. The difficulties to be overcome here are that there are deviations from the normal stress not only when the sought fault occurs, but also can occur for other reasons, so that also when scanning an error-free Surface in the photoelectric converter when the light spot passes through it once Voltage fluctuations at the output of the photoelectric over the scan line are regular Transducer occur, which see results from properties of the scanning device itself In photoelectric scanning devices for moving webs it is to achieve one that has a constant intensity over the entire width of the web to be tested Scanning light spot already known, a parabolic mirror between the light source and the path to be switched into the beam path. The use of a parabolic mirror has thereby the disadvantage that this can only be set and adjusted with great difficulty. In addition, intensity fluctuations still occur here due to the effect caused by scattered light.

According to the invention, these deficiencies in an apparatus are addressed for photoelectric error control of material surfaces, in which the surface a web running over a scanning line or a sheet-like product scanned by a light beam guided transversely to the direction of passage of the product and the brightness of the light spot generated by the light beam on the scan line to a photoelectric converter (photocell, secondary electron multiplier Od. Like.) acts, thereby avoided that in the path of the transversely guided light beam a screen-like device is switched on, with which the individual sections The amount of light supplied to the scanning line is set to different values is that when scanning a defect-free surface that of the photoelectric converter voltage generated for each point of the scan line is the one for error detection gives an optimal value, preferably a constant value.

For a more detailed explanation of the invention are examples in the drawings shown for devices with which the invention is to be implemented.

F 1 g. 1 and 2 schematically a device for photoelectric Error control of the type mentioned, with only the most essential elements of the Device are shown, namely in F 1 g. 1 in a view towards the direction of passage of the product and in F 1 g. 2 in a vertical view to.

In the figures, a light source 10 is shown by optical Means 11 loins or lenses) generates a light beam 12 of limited cross-section. A rotating mirror wheel 1 directs this beam onto the surface of the object to be tested Product 14 and here creates a light spot that extends over the entire width b of the Product migrates. The rotation of the mirror wheel leaves the reflected Beam atls the position tS over the position 16 to the second end position 17 with such a high Speed wander that of the following face of the mirror wheel scanned strips as the product moves in the direction of passage adjoins the previous scanned strip or this slightly overlapped The brightness of the light beam generated on the scanning line The light spot acts on the photoelectric converter 18 shown in FIG. 2 one, which is expediently designed as a so-called photomultiplier, and one light-collecting device, such as a cylindrical lens 19, can be connected upstream.

According to the Eri indung is in the illustrated device as Aperture acting body 20 switched on, whose Aiessungen are chosen so that the scanning light beam all the way between positions 15 and 17 is detected by the aperture. In Fig. 2 it is indicated that the mirror wheel The bundle of rays running to the surface of the product has a certain width a and that the baffle 2 smoke covers the beam along its entire width.

For the execution of the visor body are in Figs. 3 to 5 examples shown, the embodiment of Fig. 3 (plan view) and F i g. 4 (cross section) shows a slit diaphragm as an example.

It has already been said as a task of the ideology that with it the den Individual sections of the scan line fed Lionanenge to different Values should be set so that when scanning a flawless surface the voltage generated by the photoelectric converter 18 has a constant value has The in F i g. 1 and 2 shown example shows that such constant tension not without further ado, for example without considering the Aperture 20, can be generated. In this case, rather when scanning a errorfvQien surface the voltage generated in the photomultiplier 18 must be the highest, when the scanning beam hits the center of the web width b, and lower values in the beam positions 15 and 17. Ri3r the evaluation of the in the converter 18 generated, but it is advantageous and in this case even necessary, bring the voltage generated by the converter to a constant value, in particular then, when the respective actual value of these voltages to the discovery and anaeige also smallest deviations from normal reflection should be used. The after The visor body 20 to be added to the invention also solves the described problem simplest means. In the example shown, it is designed so that let him reduce the amount of light he let through in his midst, but in his own Leaves ends almost unaffected.

In the example a according to FIGS. 3 and 4, this effect is achieved by that on a translucent plate (glass plate) 21 two opaque permeable Body 22 and 23 (sheet metal plates) are placed, between which a slot is free which is narrower in the middle than at both ends, where the width of the slot is Value a according to FIG. 2 reached or only slightly below.

From the above it can be seen that the entrance the intended effect of the diaphragm from the correct dimensioning of the slot width depends. There is initially the possibility of calculating the necessary slot width to be determined according to the physical laws of optics. In most cases it appears however, it is easier to determine the diaphragm shape by eonerz calibration process; in Fig. 6 and 7 of the drawings is therefore an additional calibration device for production , of the blind mental body represented. F i g. 6 shows the glass plate on a somewhat larger scale 21 with the riveted sheet metal plate 22, the effective edge 24 of which is straight is. The plate 21 rests in the recess of an inserted into the device opaque floor 25. The calibration is carried out on the finished control device, the body 21 occupying the final position of the visor body.

To determine the correct slot width x at every point on the panel to be able to, the plate 23 according to Figure 3 and 4 is replaced by a large number of narrower Sheet metal plates 26, each of which can be adjusted in its position by means of a screw 27 is. The details of the adjustment device are shown by FIG. 7 explained in more detail, which is a section through this adjusting device in the plane VII-VII according to FIG. 6 shows. The individual sheet metal plates 26 are held by a strip (metal strip) 28 worn, the square holes corresponding to the width c of the plates 26 spacing 30 has In these holes nut body 31 are used, with a foot fitting in Ida's hole 30, which passes through a longitudinal slot 32 of the individual sheet metal plates 26 is pushed through. An eye body 33 is fixed to each sheet metal plate 26 tied together. The screw 27 is then screwed into the nut 31 after previously a cylindrical compression spring 34 was also inserted between the bodies 31 and 33. With the help of the screw 27, the effective front edge of the plate 26 can now be exactly can be set and at the same time the respective slot width x. The whole The device is then put into operation with the exception of the drive motor for the Mirror wheel 13; with the output of the transducer 18 also becomes a highly sensitive one Voltmeter connected. The calibration is then carried out in such a way that the Mirror wheel 13 is brought into such a position that the incident light beam 12 falls approximately in the direction 15 on one end of the web width. The one lying here Einzeiplatte 26 is adjusted by the associated screw 27 so that the gap width at this point almost the entire width of the beam according to Fig. 2 is covered, and it the voltage on converter 18 is read off. Then the mirror wheel 13 is made by hand rotated further until the beam falls on the next single plate 26, and the position this plate is then adjusted with the associated screw 27 so that at the transducer 18 results in the same voltage as in the previous plate. This procedure is continued over the entire length of the plate 21 with the result that at the end the exact dimension for the respective width of the slot x between the the slot delimiting bodies for any multitude of points that are only from the width c of the individual plates 26 depends, is determined. After the position of the Individual plate 26 can therefore be used to determine the curve which the edge of plate 23 must be obtained in order to achieve the desired continuous change in the applied to the scan line To achieve the amount of light. According to the curve determined with the calibration device So produce the slot-delimiting sheet 23, which is then used for the final Operation on the plate 21 is attached. The parts of the calibration device can for the calibration of a control device manufactured later without further ado use.

It should also be noted that the switching on of the diaphragm according to the invention in the to measure the Surface features used light beam is not limited to the example shown in FIGS. 1 and 2, but also can be used with any other device of a similar type. For example it is known to observe the scan line in a control device two or more photoelectric converters, the position of which is chosen so that the voltage produced by these transducers does not differ significantly from one shows constant value. Even with such systems, the activation of the aperture is similar Device according to the invention advantageous in order to also completely eliminate the aforementioned deviations to eliminate. This then results when using a slit diaphragm according to FIG. 3 a wave-shaped curve with several turning points for the edge of the plate 23, at which is the average reduction in the amount of light applied to the scan line is only limited to small values.

The slit diaphragm shown in FIGS. 3 and 4 is also only one of the possible embodiments for the design of the screen-like device. For example, the slit diaphragm can also be replaced by a device as shown in FIG. 5 is shown. Here is a layer on the glass body 21 35 applied, which is at least partially translucent and over the length the plate 21 can be given a different light absorption. This is possible by using a conventional photographic emulsion as layer 35 the body 21 is applied and by a photographic development after different Exposure creates a more or less strong gray haze in this layer will. So it can be the extinction capacity of this gray slice for each point the length of the plate 21 can be set to such a value that also at Activation of this filter by the photoelectric converter when scanning a flawless surface produced the same voltage for every point on the scan line Value results. Another possibility for an embodiment according to FIG. 5 exists therein, on the glass plate 21, a layer 35 of constant absorbance to apply and the thickness of this layer by sanding down the length of the plate to set different values, so that in the places largest Thickness of the light beam guided through the plate is more reduced in its amount of light than in the places where the thickness is less or decreases to zero. Another There is a possibility of achieving the same effect with a promising approach given by the fact that several strips of film of uniform extinction capacity glued to the glass plate 21 and the length of each strip dimensioned so that an the individual sections along the length of the plate each have the desired total extinction is achieved.

Finally, it should be noted that with the involvement the visor body achievable effect occurs even when the visor body not switched into the path of the transversely moved light beam on the way to the scanning line will, but in the path of the light radiation on the way from the scan line to aden the photoelectric converters, that is to say about the one designated by the number 36 in FIG Steep. Such an embodiment of the device is also in the range of Inventive idea.

Claims (5)

Claims: 1. Device for photoelectric error control of material surfaces, in which the surface of a material runs over a scan line Web or sheet-like product through a transverse to the direction of travel of the product guided light beam is scanned and the brightness of the Light beam on the scan line generated light spot on a photoelectric Converter (photo cell, secondary electron multiplier or the like) acts, d a d u r c h marked that in the path of the transversely guided light beam a diaphragm-like Device is switched on, with which the individual sections of the scan line supplied amount of light is set to different values so that when scanning a defect-free surface the voltage generated by the photoelectric converter for each point of the scan line the optimal value for finding the error results, preferably a constant value. 2. Apparatus according to claim 1, characterized in that as a diaphragm device a slit diaphragm is used, in which the setting of the for each point of the Scanning line required amount of light by appropriate dimensioning of the slit width he follows. 3. Apparatus according to claim 1, characterized in that as a diaphragm device a partially translucent body with different light absorption is used in which the setting is required for each point on the scan line Amount of light by appropriate measurement of the extinction capacity of the switched on Body takes place. 4. Apparatus according to claim 3, characterized in that as a diaphragm device a translucent body is used, the one for the partial absorption of Light rays carries a suitable layer, in which the layer thickness or the absorption capacity is adjusted to the amount of light necessary at each point on the scan line. 5. Device according to one of claims 1 to 4, characterized by the modification that the shutter means in the path of light from the scan line to the photoelectric converter is turned on. Documents considered: German Auslegeschrift No. 1 122 284; French Patent No. 1,263,690; General paper review, 1961, No. 2, pp. 78, 79.