LU88285A1 - Method for determining the iron content in an iron-zinc alloy coating - Google Patents

Description

Method for determining the iron content in an iron-zinc alloy coating.

The present invention relates to a method for determining the iron content in an iron-zinc alloy coating, obtained by a galvannealing operation.

The galvannealing process is a currently well known technique for forming iron-zinc coatings on steel strips. In principle, this technique consists of depositing a zinc coating on a steel strip by dip galvanizing and then annealing the coated strip to cause the diffusion of iron from the strip into the zinc layer.

The composition of the alloy layer thus obtained, also called intermetallic layer, conditions various properties of the coated strip, in particular its aptitude for welding and painting, or even its corrosion resistance. Experience has shown that these properties depend essentially on the iron content of the iron-zinc intermetallic layer. Knowledge of this iron content and its distribution on the surface of the coated strip is therefore very important for the conduct and regulation of the galvannealing operation.

In current practice, the iron content of the coating is determined by various methods, which fall into two broad categories.

The first category involves destructive chemical methods, which involve taking a sample of the coated product, dissolving the coating and analyzing the solution to determine its iron content. The result of this analysis is only known after a fairly long time, usually several minutes after the sample has been taken.

This type of method is not applicable for the continuous control of a gaivannealing line.

Another category of non-destructive methods are known which are based on X-ray fluorescence. These methods consist in bombarding the surface of the coated strip with penetrating rays, such as X-rays, at an angle d 'predetermined incidence and analyze the reflected spectrum. These methods generally use two measurements, carried out at different angles of incidence to eliminate the influence of the high iron content of the underlying steel strip.

These methods are applicable in continuous processes. However, they require the use of expensive and bulky equipment and they require major adaptations of the production line, in particular to perfectly stabilize the coated product at the location of the measurement. In addition, it is difficult to obtain and maintain good measurement accuracy due to the sensitivity of the devices to fluctuations in measurement distances and angles and to variations in ambient temperature and humidity.

The object of the present invention is to propose a method for determining the iron content in an iron-zinc alloy coating, which does not have the drawbacks of the above-mentioned methods. It allows online measurement, if necessary over the entire surface of the product, without requiring expensive, bulky and delicate equipment.

It is based on the unexpected observation, according to which there is a relationship between the iron content of the alloy coating on the one hand and certain physical quantities characterizing this coating and measurable during the process on the other hand.

According to the present invention, the method for determining the iron content in an iron-zinc alloy coating, said alloy coating being formed on a moving steel strip by a dip galvanizing operation followed by a diffusion annealing ( galvannealing), is characterized in that the intensity of the light radiation emitted by said coating is measured in a range of one face of the strip, in that the coating load is measured in this same range of strip, and in that the iron content of said alloy coating is deduced therefrom in said strip range.

It should be clarified that for the purposes of the present application, the light radiation is not limited to the visible range but that it also includes the ultraviolet and infrared ranges. Furthermore, the coating load, which expresses the weight of coating metal per unit area of the strip, is generally measured by a coating thickness measuring device. Finally, the term range here designates a portion of the surface of the strip, which can be as small as desired.

Said measurements of the intensity of the light radiation and of the coating charge of a range of the strip are advantageously carried out simultaneously at the same location on the trajectory of the strip.

However, it is not always possible, in practice, to carry out these two measurements at the same time, for various reasons such as the size of the necessary measuring devices, which prevents their installation in the same place, or the prior existence of the two measuring devices at separate locations on the tape path. In any case, these distinct places are known as well as the distance which separates them along said trajectory.

In this case, a first measurement is made at the instant when said range reaches the first of said measurement locations, the tape speed is measured, the time taken by said range to cover the distance separating the first and the second measurement location, the second measurement is made at the instant when said range reaches the second of said measurement locations, and the iron content of said alloy coating in said range is deduced therefrom.

According to a first implementation, the intensity of the light radiation from the coating is first measured and then the coating load deposited on the strip. This solution is often applied in practice, for the simple reason that a coating thickness measuring device exists in many coating lines and is generally located in a place where the coating alloying process is completed and where the coated product is completely cooled.

Another implementation consists in first measuring the coating charge and then the intensity of the light radiation from this coating. Under these conditions, it is possible to predict the iron content that the final alloy coating will have, and this at the moment when the measuring range of the strip passes through the place of measurement of the intensity of the light radiation, it is that is, even before the process of forming the alloy coating is completely completed.

The two aforementioned implementations lead to an identical final result. The first implementation proposed makes it possible to use only measuring devices which exist in most installations; on the other hand, the response time is extended by the time taken by the strip range to pass from the first to the second measurement location; this additional period is never very long, however, and is generally less than 1 minute. From a practical and economic point of view, the second implementation has a shorter response time, and therefore a faster reaction in the event of a significant deviation to be corrected; on the other hand, it requires the installation of an additional device for measuring the coating charge upstream of the device for measuring the intensity of the light radiation.

According to an additional characteristic, said measured iron content is compared with a reference value of this iron content, and at least one of the operating conditions of the galvannea-ling operation is adjusted so as to reduce, and preferably, to cancel, the difference possibly noted between the measured value and the reference value of the iron content of said alloy coating. To this end, it is in principle possible to act on the actual coating step, so as to modify the coating load deposited on the strip. In general, however, this characteristic is imposed for other reasons, in particular to ensure a determined resistance to corrosion, and it cannot therefore be modified appreciably.

One can also act on the gaivannealing temperature, or on the distribution of this temperature, to vary, homogeneously or heterogeneously, the rate of diffusion of iron in the zinc coating.

According to a particular implementation, said intensity of the light radiation from the strip is measured at a point in the trajectory of this strip which corresponds to the appearance of the dzeta phase (f) in the coating. This phenomenon expresses the arrival of the first iron atoms on the surface of the alloy coating. This measurement can also be carried out downstream of the place of appearance of the dzeta phase (f), that is to say at a place of the trajectory where the surface of the coating already contains iron, but before the part of the trajectory where the iron content reaches its final value.

According to another characteristic of the process of the invention, said measurements are carried out in several ranges distributed along the width of the coated strip, in order to establish transverse profiles of the iron content of the alloyed coating. It is thus possible to draw up a map of the distribution of the iron content of the alloyed coating on the surface of the strip, and therefore to more effectively correct the deviations observed with respect to reference values. This characteristic of the invention makes it possible not only to guarantee that the desired iron content is obtained, but also to obtain good transverse homogeneity thereof on the strip. In a manner known per se, these areas can be scanned either individually by a plurality of devices, or periodically by a single device scanning the strip along its width.

In the context of the present method, the aforementioned measurements can be carried out on each of the two faces of the strip; this possibility is particularly advantageous when the coating charge and the iron content of this coating are not identical on the two faces of the strip.

Likewise, the aforementioned measurements can be carried out at predetermined time intervals, and preferably continuously, on the coated moving web.

The measurement of the intensity of the light radiation can be carried out at any wavelength or in any range of wavelengths, located in the infrared, visible or ultraviolet range. However, it is preferable to carry out this measurement in the infrared range, and more particularly in a wavelength range of between 0.75 IM and 15 im. It is indeed well known that infrared radiation has, in this wavelength range, a high intensity and a significant signal / noise ratio, which favor the accuracy of the measurements. The invention will now be explained in more detail, by means of a particular example of implementation illustrated by the appended drawings, in which the:

Fig. 1 shows a galvannealing installation, where two measurement points have been indicated which can be used in the context of the invention; the

Fig. 2 illustrates a comparison between the results of a continuous measurement according to the invention and of a usual chemical analysis; Fig. 3 shows the correlation between the measured values and the calculated values of the iron content of the same coating.

In Fig. 1, a galvannealing installation is shown diagrammatically, which essentially consists of a dip galvanizing tank 1, a coating thickness adjustment system 2 and an annealing oven 3.

A steel strip 4 runs through this installation in the direction indicated by the arrows; in a manner known per se, it is deflected by a series of suitable deflection rollers. The strip first passes through a zinc bath 5 contained in the tank 1, where it receives its zinc coating. At the exit of the zinc bath 5, this coating is still in the molten state; its thickness is adjusted by a suitable device 2, such as generally hot air knives. The coated strip then passes into the annealing furnace 3, where it is heated and maintained at a temperature and for a determined period of time to cause the diffusion of the iron from the strip into the zinc coating. This diffusion continues while the strip cools after leaving the oven ^ 3; the final thickness of the coating, also called coating charge, is measured on the cooled strip by means of a measuring device 6. There is a measuring device of this type in most galvannealing installations. This measuring device does not by itself provide any indication of the iron content of the coating.

By means of an additional measuring device 7, the intensity of the infrared radiation emitted by the coated strip is measured, after its annealing in the oven 3.

As indicated above, the measuring device 7 is preferably placed at the place of appearance of the dzeta phase (f). The measuring devices 6 and 7 are advantageously double devices, so as to allow measurements on the two faces of the strip.

Finally, the speed of the strip 4 is measured by any means known per se, symbolized by a tachometer 8. The latter can be placed anywhere in the trajectory of the strip; preferably choose an easily accessible place protected against disturbing effects of mechanical or thermal origin.

Signals representative of the coating charge (Ch), of the intensity (I) of the light radiation, in particular infrared, of the coating and of the speed (V) of the strip, produced respectively by the apparatuses 6, 7 and 8 , are introduced into an electronic processor 9, where they are processed according to a predetermined program to produce a signal representative of the iron content of the alloyed coating, by a relationship of the type Fe = f (I, V, Ch).

This program can also take into account characteristic parameters of the strip, in particular its thickness, its width or its composition, in particular its carbon content, as well as characteristic parameters of the coating itself, in particular its zinc content. or possible alloying elements.

The signal obtained is compared with a reference value of the iron content of the coating and, as a function of the result of this comparison, the processor 9 produces signals for adjusting the temperature of the annealing furnace 3 and possibly the thickness of the coating by air knives 2.

In Fig. 1, only one device 6 and 7 has been shown, for each face of the strip; this unique device is usually placed opposite the center line of the strip. There is thus a longitudinal profile of the iron content in the center of the strip.

Without departing from the scope of the invention, it is possible to place several devices 6,7 distributed along the width of the strip, or even the single devices 6,7 can be moved in an oscillating movement in the transverse direction. It is thus possible to carry out measurements over the entire width of the strip and to establish a map of the iron content throughout the surface of the coated strip. In this case, the processor can produce signals correcting, for example, heterogeneities in the coating in the system 2 or in the heating in the oven 3.

Fig. 2 illustrates a comparison between the results of a continuous measurement according to the invention on the one hand, represented by a continuous curve, and of a usual chemical analysis on the other hand, represented by a series of points. The continuous curve is a longitudinal profile of the iron content (Fe -%) recorded as a function of time (t - h) along the center line of a strip. Fig. 2 shows a good correspondence between the results, obtained online continuously and the laboratory results available later.

Fig. 3 shows the correlation between the values of the iron content of the coating measured by chemical means (A) and calculated from the parameters measured by devices 6,7 and 8 (C), for a population of 129 samples. The correlation is excellent (R2 = 0.830; a = 0.55).

Claims (10)

1. Method for determining the iron content in an iron-zinc alloy coating, said alloy coating being formed on a moving steel strip by a dip galvanizing operation followed by a so-called galvannealing diffusion annealing, characterized in that the intensity of the light radiation emitted by said coating is measured in a range of the surface of the strip, in that the coating load is measured in this same range of the strip, and in that the the iron content of said alloy coating is deduced therefrom in said range of the strip. 2. Method according to claim 1, characterized in that the intensity of the light radiation and the coating charge of said area are measured simultaneously at the same place on the path of the strip. 3. Method according to claim 1, characterized in that two separate measurement locations are established on the path of the strip, in that a first measurement is made at the moment when said range reaches the first of said locations of measurement, in that the tape running speed is measured and the time taken by said range to cover the distance separating the first and the second measurement locations is determined, in that the second measurement is carried out at the instant when said range reaches the second of said measurement locations, and in that the iron content of said alloy coating in said range is deduced therefrom. 4. Method according to either of claims 1 to 3, characterized in that said intensity of the light radiation is measured at a location on the trajectory of the strip which corresponds to the appearance of the dzeta phase ( Ç) in the coating. 5. Method according to either of claims 1 to 3 /, characterized in that the said intensity of the light radiation is measured at a point on the path of the strip situated between the point which corresponds to the appearance of the dzeta phase (f) in coating X and the place where the iron content of the coating reaches its final value. 6. Method according to either of claims 1 to 5, characterized in that at least one of said measurement locations located on the trajectory of the strip, the coating load is measured, respectively the intensity of the light radiation from the coating, in a plurality of areas distributed along the width of the strip, and in that at least one transverse profile of the iron content of said alloy coating is established. 7. Method according to one or other of Claims 1 to 6, characterized in that the coating charge and the intensity of the light radiation from the coating are measured on both sides of the strip. 8. Method according to any one of claims 1 to 7, characterized in that said intensity of the light radiation of the coating is measured in the infrared range, and preferably in a wavelength range between 0.75 / "η and 15 pm. 9. Method according to either of claims 1 to 8, characterized in that the said iron content determined from measurements of the coating charge, of the intensity of the light radiation of the coating is compared and of the speed of the strip, with a reference value of said iron content and in that, depending on the difference observed between the measured value and the reference value of iron content, the operation of thickness control and / or annealing operation after galvanizing so as to reduce, and preferably cancel, the difference found. 10. Method according to claim 9, characterized in that at least one of the operating conditions is regulated from among the thickness of the coating and the temperature of the annealing after galvanization as a function of said deviation observed.