CZ304928B6 - Process for producing steel strips by hot rolling - Google Patents

Abstract

According to the invention, a pre-strip (V), which is close to the final dimensions and which has a thickness of up to 6 mm is cast from a steel containing more than 12 to 30 percent by weight of manganese in a two-roll casting machine (2). After casting, said pre-strip is continuously hot-rolled in preferably one single pass. The inventive method enables the production of steel strips, which have good deformation behavior despite their high content of manganese.

Description

Process for producing hot rolled strip steel

Technical field

The present invention relates to a process for producing hot rolled strip steel having the properties of TWIP and TR1P from steel containing more than 12% and up to 30% by weight of manganese in which the melt is cast into a billet. Steels of this type are characterized by a particularly high strength.

BACKGROUND OF THE INVENTION

The problem with the production and processing of steels having a high manganese content is that these steels behave differently from solidification to conventional steels intended for deep-drawing applications such as IF steels or low carbon steels. It turns out that high manganese steels cast by conventional continuous casting of the billets in question behave poorly during forming.

According to the process known from DE 199 00 199 A1, steels containing, inter alia, 7 to 27% Mn by alloying elements can be produced by casting thin strips approaching the final dimensions and further processing them into strip steel. The material thus obtained is particularly suitable for use in the field of automotive bodies.

SUMMARY OF THE INVENTION

SUMMARY OF THE INVENTION The object of the present invention is to provide a process which makes it possible to produce steel strips having good forming properties despite the high manganese content.

This object is achieved by a process for producing hot-rolled strip steel having the properties of TWIP and TRIP from a steel containing more than 12% and up to 30% by weight of manganese in which the melt is cast into a billet according to the invention, In a two-roll casting machine, it is cast into a billet, close to final dimensions, up to a thickness of 6 mm, which is then continuously processed into hot-rolled strip steel by casting to a strip thickness in a single mill.

According to the invention, the high manganese steel is cast into a material whose dimensions are close to the end dimensions of the strip steel. In this way, a thin material is already produced in the casting process so that even solidification is substantially ensured over its entire cross-section. Surprisingly, it has been found that a material cast in this manner with dimensions that are close to the final has a substantially finer, more uniform structure than a steel strip manufactured by a conventional route, with a comparatively higher manganese content. Strip steel made from pre-treated material has the properties of TRIP (Transformation-Induced-Plasticity) and TWIP (Twinning-InducedPlasticity) and has correspondingly good forming ability, which, in combination with high strength, is particularly suitable for use in structures bodywork.

According to the invention, the thickness of the material produced should be as small as possible. The thinner the cast starting material is, the finer the solidification structure and the less solidification errors can interfere with further processing into strip steel. At the same time, in the case of thinly cast starting material, the solidification process can be controlled in a simple manner. Thus, the controlled process may take into account the fact that, particularly in the steels of the type discussed herein, the rate of solidification has an immediate effect on the height and distribution of the micro-aggregates. This again affects grain growth and the condition of precipitations that occur due to solidification, such as MnS, AlN and Ti (C, N). By the targeted control of the parameters of the structure of the cast starting material, the foundations can be adjusted

Have a decisive influence on the further processing capability and utility properties of the end product.

The steel casting according to the invention is carried out in a two-roll casting machine. This type of casting machine known per se makes it possible to produce a particularly thin starting material very close to the final dimensions of the strip steel, whose solidification behavior, in particular its solidification speed and uniformity of solidification, leads to an optimum casting structure and thus optimal molding.

Surprisingly, it has been shown that by producing strip steel from the billet to a final thickness for only one pass through the rolling mill, particularly good working results can be achieved. Continuous hot rolling, following a single pass through the rolling mill, allows heat to be transferred from the casting process to the rolling process so that the reheating step prior to hot rolling, which is still necessary in conventional slab casting, can be removed. Moreover, the "transfer" of the casting heat removes excessive crystal growth, thereby supporting the formation of a fine structure in the starting material.

Due to the particular effects of the solidification process on the properties of the end product, it is advantageous if further processing of the starting material into the strip steel comprises a controlled cooling operation immediately after casting. This makes it possible to specifically cool the material emerging from the casting mold so that its structure is kept optimal for further processing. In this case, cooling is generally performed at a higher cooling rate than air cooling.

Experiments have shown that, depending on the composition and the desired properties of the end product, the average initial rolling temperature at which the starting material enters the mill can be between 1100 ° C and 750 ° C.

In addition, if the starting material is hot rolled, the hot rolled properties of the strip can be specifically influenced by the cooling of the strip strip steel controlled by the hot rolling.

In principle, it is conceivable that the strip steel obtained according to the invention is further processed in-line, for example in the form of a cold strip. However, in many cases, due to the various subsequent processing steps or the necessary properties of the strip steel, it is expedient for the strip to be wound into a reel for further processing.

Since further processing of the starting material into the strip steel occurs at least in sections under a protective atmosphere, oxidation of the surface of the strip and thereby excessive scale formation can be prevented.

In this context, it is particularly favorable if the starting material is kept under a protective atmosphere at least until it enters the mill stand.

The steels that can be used according to the invention can contain up to 3.5% by weight, in particular up to 3% by weight, of silicon, among other alloying elements. In addition, they may have up to 3.5% by weight, in particular up to 3% by weight, of aluminum. Iron and aluminum or iron and silicon form intermetallic phases in the steels further processed according to the invention, which occur below the forming temperature and are stable up to room temperature.

Clarification of drawings

In the following, the invention will be explained in more detail on the basis of one exemplary embodiment according to the figures, in which Fig. 1 shows the construction of a strip steel plant in a schematic side view,

Figure 30 shows an enlarged cross-sectional view of the strip region of the strip steel produced on the apparatus of Figure 1; produced on the apparatus of FIG. 1.

DETAILED DESCRIPTION OF THE INVENTION

Giant. 1 schematically shows the construction of a strip steel production device W comprising a casting device 2, a first cooling section 3, a rolling mill 4, a second cooling section 5 and a winding device

6.

In the casting apparatus 2, embedded in the double roll machine according to the known principle, the melt S contained in the tundish 7 in the composition which will be explained in detail below is cast in a casting nip 10 formed between two casting rolls 8, 9, The cast billet V leaves the casting nip 10 in a continuous conveying process with a thickness that can vary from values less than 1 mm up to 6 mm.

On its way to the rolling mill 4, the billet V is cooled in a controlled manner by a cooling medium applied to its surface, on a first cooling section 3 arranged below the outlet of the casting slot and closely adjacent thereto.

The conveying path, which has been traveled by the thin strip V between the outlet of the casting slot 10 and the rolling stand 4, is surrounded by a housing 11 in which the shielding gas atmosphere is maintained at rest. In this way, contact of the surface of the strip with oxygen in the ambient air is prevented.

The thin strip V enters the rolling mill 4 with an initial rolling temperature ATT and is rolled in the mill pass to its end thickness.

The warm strip W leaving the rolling mill 4 with the end rolling temperature ET runs directly through the second cooling path 5. In the cooling path 5, the warm strip W is again controlled by a suitable coolant to a coiling temperature HT, with which it is finally wound up in the coil C.

The attached diagram shows the initial rolling temperature AT, the end rolling temperature ET and the winding temperature HT during the processing time after casting in the strip width, which can be adapted to the device constructed according to the figure depending on the composition and the desired properties of the hot strip produced. Due to the appropriate temperature conduction along a predetermined limit curve followed by isothermal dwell, rolling and quenching, the fine-grain structure of the hot strip is allowed to freeze upon exit from the mill stand, so that good properties for using the hot strip after hot rolling remain. This effect can be achieved especially when the temperature profile of the billet and the hot strip approaches the limit curve shown in the diagram below.

The melt S cast in the exemplary embodiment has an Mn content of 20% by weight, a C content of 0.003% by weight, a sulfur content of 0.007% by weight, a Si content of 3.0% by weight, an Al content of 3.0% by weight and iron as the remainder .

Photo 1 shows an enlarged cross-section of the edge region and Photo 2 shows an enlarged cross-sectional view of the central region of a hot strip made of this steel on the apparatus shown in the figure. It appears that the web has a tree-like structure consisting of austenite and a second phase, probably containing carbon. Significant refining of the structure is shown towards the belt core.

Claims (11)

PATENT CLAIMS Method for producing hot-rolled strip (W) having TWIP and TRIP properties from steel containing more than 12% and up to 30% by weight of manganese, in which the melt (S) is cast into a billet (V), characterized by: in that the steel is cast in a two-roll die casting machine (2) into a billet (V) close to the final dimensions with a thickness of up to 6 mm, which is further processed into hot-rolled strip steel (W) after casting, that is rolled to a final strip steel thickness (W) in a single mill. Method according to claim 1, characterized in that the thickness of the billet (V) is up to 4 mm, in particular up to 2.5 mm. Method according to one of the preceding claims, characterized in that the further processing of the billet into hot-rolled strip steel (W) comprises controlled cooling, carried out immediately after the casting. Method according to claim 3, characterized in that the cooling is performed at a higher cooling rate than in air cooling. Method according to one of the preceding claims, characterized in that the mean initial rolling temperature (AT) with which the billet enters the rolling stand (4) is between 1100 ° C and 750 ° C. Method according to one of the preceding claims, characterized in that the rolled strip steel (W) is cooled in a controlled manner following hot rolling. Method according to one of the preceding claims, characterized in that the strip steel (W) is wound into a bobbin (C) at the end of further processing. Method according to one of the preceding claims, characterized in that the further processing of the billet into the strip steel (W) is carried out at least in sections under a protective atmosphere. Method according to claim 8, characterized in that the billet (V) is kept under a protective atmosphere at least until it enters the mill stand (4). Method according to one of the preceding claims, characterized in that the steel contains up to 3.5% by weight, in particular up to 3% by weight, of silicon. Method according to one of the preceding claims, characterized in that the steel contains up to 3.5% by weight, in particular up to 3% by weight, of aluminum. 3 drawings