This is a national stage of PCT/EP09/052926 filed Mar. 12, 2009 and published in French, which has a priority of Belgium no. BE2008/0270 filed May 14, 2008, hereby incorporated by reference.
The present invention relates to an in-line method for measuring the surface cleanliness of steel sheets or strips.
During the manufacture of steel sheets, the cold rolling process essentially creates two types of impurities on the sheet surface: first, surface carbon, which comes from the degradation of the rolling oils, and secondly, iron fines from the interactions with the cylinders used for rolling.
This surface pollution is problematic because it requires more frequent cleaning of the cylinders and the pickling baths are more quickly polluted. This obviously entails additional costs. The dirty sheets also have to be annealed longer, which is also more costly. Lastly, in the subsequent galvanization or painting steps, these depositions amount to adhesion flaws that have consequences on the corrosion resistance of the finished products.
To assess the surface cleanliness, there are two different methods that can be classified in two groups:
This last method however depends on the operator, and in particular on the way that the Scotch® tape is applied on the sheet (application speed, pressure, removal speed, etc.). It results in a significant dispersion of the results, which can reach more than 20% on the reflectivity measurement.
Recently, a semi-automatic method was developed. This method allows to automatically apply the “Scotch® tape” on the sheet, which may be in motion, then to measure the reflectivity percentage, also done automatically. However, an operator is still present and the dispersion of the results is apparently only barely lower. Furthermore, the discontinuous nature of the measurements remains a major drawback (cf. CoilScooter-TG apparatus by the company INNSITEC Laser technologies GmbH—www.innsitec.com).
Even more recently, a completely automatic method based on the absorption of infrared radiation was studied. To our knowledge, it is still being developed and, in any case, is not widely spread (see Krauth P. J., “Contrôle de la propreté des surfaces d'acier”, La Revue de Métallurgie—CIT, June 2002).
The present invention aims to provide an in-line and continuous method for measuring the surface cleanliness of steel strips, which allows to overcome the drawbacks of the prior art.
The invention more particularly aims to provide a reliable, reproducible and completely automated method.
The present invention relates to an in-line and automated method for measuring the surface cleanliness of a metal sheet or strip in continuous motion, wherein:
Preferred embodiments of the invention also disclose one or several of the following features in combination:
In
In
The device proposed in the invention belongs to the category of fully-automated measuring devices. It may be placed on an industrial line and operate without operator intervention.
The principle of the device is described below.
A laser beam, preferably pulsed, is focused on the surface of the sheet in motion. The laser power and focal diameter are chosen such that the power density obtained on the sheet is sufficient to create a plasma on the surface of the sheet.
Under these conditions, one notes the formation of an oxidation ring surrounding the plasma zone. This ring has a width and a brownish color that depend on the surface cleanliness.
By analyzing the characteristics of the oxidation zone with a camera or any other equivalent device, it is possible to deduce a value indicative of the surface cleanliness independent from an operator's subjectivity.
Processing of the image consists in analyzing the width of the affected zone and/or the intensity of its coloring.
Example of Application of the Method
In the following example, the laser source used is that included in the TeleLis, LIBS laser apparatus by the firm LSA—Laser Analytical Systems & Automation GmbH, Aachen.
The laser beam, with an energy of 300 mJ, is focused 150 mm under the surface of the sheet to be measured, the source being situated 4 meters from the sheet. The sheet moves at a linear velocity of about 0.6 m/s. The laser operates in “double-pulse” mode with a repetition frequency of 20 Hz.
With each pulse, a plasma is generated and a micro-crater is created on the surface of the sheet. Its depth depends on the energy of the laser. Around the crater, a more or less dark brownish zone appears: surprisingly, it has been noted that the intensity of its color and its width depend on the surface cleanliness of the sheet.
As an example,
It is therefore noted that, for the dirty sheet, a dark ring is clearly visible around each crater, the central point being black, whereas it almost does not appear at all for the clean sheet.
If, in both cases, a well-defined zone is delimited around a crater (hatched zone in
The difference is even more pronounced if the median, which is 88 and 131, respectively, is used. In comparison, the traditional reflectivity measurements used to determine surface cleanliness yield values of about 58% and 38%, respectively. It will be noted that the reflectivity percentage values decrease the dirtier the sheet is, whereas the average value of the local histogram increases.
These criteria based on the histogram are only one of the possibilities for quantifying the cleanliness of the sheets based on an automatic image analysis. More sophisticated processing known by those skilled in the art would allow even deeper discrimination. Indeed, weak coloring of the ring is visible to the naked eye for the clean sheet, whereas the basic gray-scale conversion applied as above makes it disappear completely, thus reducing the discriminating power of the method.
For information,
Advantages Of The Method
This method has the advantage of being completely automated and therefore does not depend on the dexterity and judgment of an operator.
It may also work on a sheet in motion for continuous monitoring.
Lastly, it only requires simple and robust material, that may be used on industrial lines, at a sufficient distance to avoid damage in case of an incident.
Number | Date | Country | Kind |
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2008/0270 | May 2008 | BE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/052926 | 3/12/2009 | WO | 00 | 11/8/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2009/138262 | 11/19/2009 | WO | A |
Number | Name | Date | Kind |
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6795179 | Kumar | Sep 2004 | B2 |
Number | Date | Country |
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05-172762 | Jul 1993 | JP |
2002-195950 | Jul 2002 | JP |
Entry |
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Balzer et al. (2005) “Online coating thickness measurement and depth profiling of zinc coated sheet steel by laser induced breakdown spectroscopy.” Spectrochimica Acta Part B vol. 60, pp. 1172-1178. |
Mateo et al. (2003) “Automated line-focused laser ablation for mapping of inclusions in stainless steel.” Applied Spectroscopy, vol. 57 No. 12, pp. 1461-1467. |
Orzi et al. (2004) “Identification and measurement of dirt composition of manufactured steel plates using laser-induced breakdown spectroscopy.” Applied Spectroscopy, vol. 58 No. 12, pp. 1475-1480. |
Zhang et al. (2002) “Evaluation and control of steel cleanliness—Review.” Proc. 85th ISS-AIME Steelmaking Conf., pp. 431-452. |
P.J. Krauth, “Contrôle de la propreté des surfaces d'aciers,” La Revue de Métallurgie, 2002, pp. 561-568 (Partial English translation). |
G.M. Bilmes et al., “A real time method for surface cleanliness measurement,” Applied Physics B: Lasers and Optics, 2006, vol. 82, No. 4, pp. 643-648. |
Innsitec Laser Technologies GmbH, CoilScooter-TG, Transportable LIBS system for remote chemical elemental analysis—TeleLis, http://www.innsitec.com, (Jun. 2005). |
Number | Date | Country | |
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20110051994 A1 | Mar 2011 | US |