EP0473561A1 - A method of heat treatment of a steel product - Google Patents

Abstract

Method of heat treatment of a steel product leaving the rolling mill in which, during a first stage, the product is subjected to cooling with water to a surface temperature which is equal to or lower than the temperature of the onset of the martensite transformation (Ms point) of the steel, with a rate of cooling which is at least equal to the critical rate for quenching the steel; during a second stage the product is first of all subjected, by virtue of the heat released by the unquenched part of the product, to a reheating of the quenched surface layer to a surface temperature, known as the self-annealing temperature, of between 550 DEG C and 650 DEG C, and then to a secondary cooling to a surface temperature of less than 450 DEG C; the final cooling of the product to a temperature of less than 120 DEG C is then performed, for example with the aid of highly agitated water. During the stage which follows the self-annealing, the product may first of all advantageously be allowed to stay in air up to a temperature of approximately 550 DEG C, and then be cooled at high speed to a temperature substantially below 400 DEG C, and be reheated to a temperature of between 400 DEG C and 420 DEG C before being allowed to cool in air. <IMAGE>

Description

The present invention relates to a method of heat treatment of a steel product, preferably carried out immediately after the rolling of this product.

The method of the invention is particularly applicable to long products, which generally undergo, after rolling, cooling on a cooler. These include beams, sheet piles, rails, bars and merchant bars of the most varied sections, but also tubes of any shape.

In conventional current practice, long products of the aforementioned types leave the rolling mill at a temperature above their point Ar₃ and they are deposited on a cooler where they are cooled in air to room temperature. This practice requires long cooling times and offers no possibility of adjusting the intensity and duration of this cooling.

In a technique, known in particular by patent BE-A-834059, a surface quenching treatment is applied to the profile, at its exit from the last stand of the rolling mill, when it is at a temperature above its point Ar₃ and self-income. In practice, the profile is subjected to accelerated cooling with water, which causes the hardening of a surface layer of the product. This is then deposited on a cooler where it undergoes slow cooling with calm air, firstly comprising self-tempering of the hardened surface layer.

Treatments of this kind especially make it possible to modify the microstructure of the steel and thus often dramatically improve the physical properties of the treated product. However, they do not make it possible to reduce the total duration of the cooling cycle significantly compared with simple cooling in air.

The use of a cooler, which is necessary in the aforementioned methods, gives rise to a wide variety of drawbacks, which are added to the long duration of cooling in still air. Indeed, the products undergo a fairly significant surface oxidation during their long-term stay in the air. In addition, the operation of the cooler requires numerous manipulations of the products, which are expensive and which risk causing defects. Finally, the products leaving the rolling mill, called parent products, are often cut to the desired length, into daughter products, before being placed on the cooler. It is generally necessary to use several chillers in parallel for the simultaneous cooling of the various daughter products, which entails risks of confusion between these products. In addition, the efficiency of the dressing operation is reduced because it is performed on the daughter products, of limited length.

The object of the present invention is to propose a process for heat treatment of a steel product of the aforementioned type, which can be carried out in a much shorter time than the previous processes and which makes it possible to minimize deformation during cooling. The method of the invention allows the in-line cooling of the parent products leaving the rolling mill, as well as the dressing of these products, also in line, before their cutting to the desired length. It greatly reduces handling of the products and it leads to products having excellent mechanical properties, in particular high strength accompanied by high ductility and resilience.

According to the present invention, the method of heat treatment of a steel product at the outlet of the rolling mill, is characterized in that during a first step the product is subjected to rapid cooling with water from the temperature at the end of rolling up to a surface temperature equal to or lower than the temperature at the start of the martensitic transformation, known as the Ms point, of said steel, with a cooling rate at least equal to the critical quenching speed of said steel, in what, at during a second step, the product is first subjected to a self-tempering phase, during which, thanks to the heat given off by the unhardened part of the product, the hardened surface layer is reheated up to a surface temperature, called self-tempering, between 550 ° C and 650 ° C, and then to a secondary cooling phase, which involves cooling of said product to a surface temperature below 450 ° C, and in that, during a third step, the final cooling of the product is carried out to a temperature below 120 ° C.

According to a first embodiment of the method of the invention, said secondary cooling phase consists of cooling in air to a temperature below 420 ° C.

According to another embodiment of the process of the invention, the product is cooled in air to an intermediate temperature between 450 ° C and 420 ° C during said secondary cooling phase, then it is cooled up to a temperature below 80 ° C, during final cooling. This final cooling is preferably carried out with water, in particular to limit the duration of the treatment.

According to a particularly advantageous embodiment of the method of the invention in which the cooling is carried out which follows the self-tempering phase in an even more nuanced and more controlled manner, the product is first allowed to stay in the air up to a temperature of approximately 550 ° C., it is then cooled at high speed to a surface temperature substantially below 400 ° C., the product is then reheated by dissipation of the internal heat to a temperature between 400 ° C and 420 ° C, cooling in air is carried out, then the final cooling is abruptly carried out to a temperature below 120 ° C.

Preferably, this abrupt final cooling is water cooling.

According to an additional characteristic, the method of the invention is implemented continuously, with the product leaving the last rolling stand and then traversing the treatment device. After the final cooling according to one or the other embodiment, the product is drawn up continuously, then it is cut to the desired length.

• Fig. 1 illustre schématiquement une installation permettant la mise en oeuvre des différentes formes d'exécution du procédé de l'invention; la
• Fig. 2 représente le diagramme de l'évolution de la température de la surface du produit au cours du traitement thermique objet de l'invention, lorsque ce traitement thermique comporte durant la deuxième étape, un refroidissement secondaire effectué sans discontinuité à la suite de la phase d'auto-revenu; et la
• Fig. 3 représente le diagramme de l'évolution de la température de la surface d'un produit lorsque le refroidissement secondaire comprend un refroidissement rapide et un revenu intermédiaire.

The process of the invention will now be explained in more detail, with reference to the accompanying drawings, in which the

• Fig. 1 schematically illustrates an installation allowing the implementation of the various embodiments of the method of the invention; the
• Fig. 2 represents the diagram of the evolution of the temperature of the surface of the product during the heat treatment object of the invention, when this heat treatment comprises during the second stage, a secondary cooling carried out without discontinuity following the phase d 'self-income; and the
• Fig. 3 represents the diagram of the evolution of the temperature of the surface of a product when the secondary cooling comprises rapid cooling and an intermediate tempering.

The figures do not include a particular scale; there are shown only the elements necessary for a good understanding of the invention.

The description given below refers to the cooling of profiles of different thicknesses. It is of course in no way limiting, in particular as regards the durations of the various cooling stages and the intensity of the cooling. These parameters are adapted in a manner known to those skilled in the art depending on the type and analysis of the product.

The reference numeral 1 in FIG. 1 designates the rolled steel product, in this case a profile, which moves in the direction of arrow 2. This product circulates continuously in a series of devices where it is subjected to the stages of successive cooling, corresponding to the diagrams in Figures 2 and 3.

The product 1 leaves the last stand of the rolling mill, symbolized by a pair of cylinders 3, and immediately enters a first cooling device 4. This first device, known per se, consists of a tube of appropriate section, filled with circulating water. Product 1 undergoes abrupt surface cooling there, from the end of rolling temperature to a surface temperature below the point Ms of the steel in question; during this first cooling (of duration t1), a layer of martensite is formed on the surface of product 1.

In a manner also known per se, the thickness of this surface layer of martensite depends on the speed and intensity of the cooling, that is to say in fact on the duration t1 and on the surface temperature of the product to be the end of cooling.

After this first stage of the heat treatment, the product 1 is transferred to a cooler 5, where it is subjected to in-line cooling according to one or the other embodiment of the method of the present invention. In all cases, the product undergoes a first phase, self-income phase, during which there is an equalization of the temperature between the core and the surface of the product; the core cools and the surface heats up to a temperature between 550 ° C and 650 ° C, which causes self-tempering of the surface layer of martensite. The self-income phase has a duration t2. The differences between the forms of execution relate to the operations which follow the self-income phase.

A first embodiment is illustrated in FIG. 2, which represents the temporal evolution of the surface temperature of the product when the secondary phase of the second stage of the process consists only of air cooling.

In this embodiment, this secondary phase, of duration t3, consists of air cooling of the product to a temperature below 450 ° C, and preferably below 420 ° C. The duration t3 of this cooling in still air naturally depends on the type of product, in particular on its thickness. It is essential to allow the product to cool in air to a temperature below 450 ° C, and preferably below 420 ° C, to guarantee good resilience of the final product. If the final cooling, that is to say the third stage of the process, is applied, from too high a temperature, the residual austenite which is not yet transformed and enriched in carbon can transform into martensite and give rise to a fragile structure. This final cooling, of duration t4, is carried out with water to limit the duration of the treatment; it should no longer have a metallurgical effect.

The diagram in FIG. 3 represents the temporal evolution of the surface temperature of the product, when the second phase of the second stage of the process successively comprises air cooling (t31), intense cooling (t32), an auto -heating (t33) and air cooling (t34).

In this embodiment, the air cooling (t31), immediately after the self-tempering of the martensitic surface layer, brings the surface temperature of the product down to around 550 ° C. An intense cooling (t32) is then carried out, generally with circulating water, from this temperature of approximately 550 ° C. to a surface temperature of 300 ° C. After a residence time (t33) ensuring the equalization of the temperature on the product section up to 400 ° C, air cooling (t34) is carried out from 400 ° C to 300 ° C during which performs the ferrite overaging reaction; then the final cooling (t4) constituting the third step of the process is carried out. This final cooling is carried out with water up to the temperature of 80 ° C., temperature at which the product can be handled without being altered.

Intermediate cooling (t32) can be carried out in a device 5 ′, shown in phantom in Figure 1 because it is not used in all embodiments of the method of the invention. This device 5 ′, as well as the device 6 where the final cooling takes place (t4) essentially consists of a tube of appropriate section traversed by water. In Figure 1 attached, it should be understood that the device 6 is arranged following the cooler 5; the mixed line which connects them expresses this arrangement while making it possible to limit the size of the drawing.

At this stage, that is to say after the final cooling (t4), the product 1 is still in continuous form, as it left the rolling mill 3. The cooling operations are carried out so as to provide the produces good straightness.

After the final cooling with water, the product 1 can still be dressed in a dressing device 7, then a shear 8 cuts it into sections of desired length, which are evacuated by an outlet conveyor 9. The dressing must be carried out at a temperature below 120 ° C and preferably below 80 ° C to avoid any subsequent deformation.

By way of example, the following two tables indicate typical cooling times for the different stages of the process of the invention, in the case of profiles of different thicknesses. The thicknesses e of the profiles are expressed in millimeters (mm) and the times (t _i ) are expressed in seconds (s).

Table 1 corresponds to the first embodiment described above and shown schematically in Figure 2. The duration of self-income (t3) increases rapidly with the thickness of the profile, and risks becoming prohibitive for products of very thick (> 40 mm); it is therefore interesting to insert intense cooling in the second phase of the second stage of the process, as shown in Figure 3.

Table 2 illustrates this embodiment. We note that it brings in all cases a significant time saving (about 20 minutes for products of 125 mm thickness). This time saving does not harm the quality of the products, because they have good straightness, high resistance, as well as excellent resilience at any point in their section.

The method of the invention makes it possible to carry out the entire treatment, including dressing, on the parent products, that is to say as they come out of the rolling mill. We thus significantly reduce the number of manipulations required and therefore the risk of the appearance of faults linked to these manipulations. Finally, only one short cooler is used since the stay in the air is short, which limits on the one hand the risk of confusion between the products and on the other hand the degree of oxidation of the product surface.

Claims (7)

Process for heat treatment of a steel product at the outlet of the rolling mill, characterized in that during a first step, the product is subjected to rapid cooling with water from the end of rolling temperature to a surface temperature equal to or lower than the temperature at the start of the martensitic transformation, known as the Ms point, of said steel, with a cooling rate at least equal to the critical quenching speed of said steel, in that, during a second step, the product is first subjected to a self-tempering phase, during which, thanks to the heat given off by the unhardened part of the product, the hardened surface layer is heated up to a surface temperature, called self-tempering, between 550 ° C and 650 ° C, and then at a secondary cooling phase, which involves cooling of said product to a surface temperature below 450 ° C, andin that, during a third step, the final cooling of the product is carried out to a temperature below 120 ° C. Process according to Claim 1, characterized in that during the said secondary cooling phase, the product is cooled in air to a temperature below 420 ° C, Process according to Claims 1 and 2, characterized in that, after the product has reached its self-tempering temperature, the product is allowed to remain in the air up to a temperature of about 550 ° C, in that that it is then cooled at high speed to a temperature substantially below 400 ° C, in that the product is allowed to warm up to a temperature between 400 ° C and 420 ° C, in that the 'is carried out a slow cooling in the air and in that one proceeds to a final abrupt cooling to a temperature below 120 ° C. Process according to either of Claims 1 to 3, characterized in that the product is cooled to a temperature below 80 ° C during said final cooling. Process according to either of Claims 1 to 4, characterized in that the said final cooling is cooling with highly agitated water. Process according to either of Claims 1 to 5, characterized in that it is implemented immediately after the exit from the last rolling stand. Process according to either of Claims 1 to 6, characterized in that it is carried out continuously.

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