EP3781717A1 - Cold-rolled flat steel product, use and method for producing such a flat steel product - Google Patents

Abstract

The invention provides a high-strength, cold-rolled flat steel product which is highly reliable in satisfying the practical requirements for its usability, has an n value of at least 0.21, and can be reliably produced on an industrial scale. To this end, the flat steel product is made of a steel which consists of (in wt%) C: 0.08 - 0.25 %, Al: 3 - 5.4 %, Mn: 6 - 14 %, B: 0 - 0.1 %, Cr: 0 - 2 %, Si: 0 - 0.4 %, P: 0 - 0.1 %, S: 0 - 0.3 %, Ta: 0 - 0.5 %, W: 0 - 0.5 %, Ni: 0 - 2 %, Cu: 0 - 2 %, Ca: 0 - 0.15 %, N: 0 - 0.02 % Co: 0 - 2 % and one or more elements from the group "Ti, Nb, V and Mo", with the proviso that the sum of the contents of these elements is 0.05 - 1 %, and/or one or more elements from the group "Zr, La, Ce and Y", with the proviso that the sum of the contents of these elements is 0.05 - 0.3 %, and consists of residual iron and unavoidable impurities, wherein %Mn/%Al > 1.2 applies to the ratio %Mn/%Al, and 3 < Al_eq < 8 applies to Al_eq = %Al + 0.4 x (%Si)³ - 3 x (%Si)² + 8.3 x %Si, where %Mn, %Al and %Si are the Mn-, Al-, and Si-contents of the steel, and the microstructure of 10 - 60 area% of the flat steel product is austenitic and 40 - 90 area% is ferritic with an austenitic particle mean size of 0.85 - 3 μm. In addition, the invention provides a method for producing such a flat steel product, said method comprising final annealing as the fundamental work step, carried out as continuous annealing over 20 s - 10 min at 950 - 1070°C or as box annealing over 0.5 - 60 h at > 850 - 950°C.

Description

 Cold rolled flat steel product and use and method of making such a flat steel product

The invention relates to a cold-rolled flat steel product which has an optimum combination of its mechanical properties for the forming into components, in particular vehicle components and the like.

Furthermore, the invention relates to a method for producing such a cold-rolled steel flat product.

Likewise, the invention calls for such flat steel products particularly suitable uses.

If contents of a steel or a flat steel product are mentioned in the present text, these contents always refer to the weight (stated in% by weight), unless expressly stated otherwise. If information on the composition of atmospheres or gas mixtures is given in the present text, these relate to the individual

Ingredients content information always made on the volume (in Vol .-%), unless otherwise stated. Are in

present text Information on the contents of individual constituents in the microstructure of a flat steel product, these always refer to the proportion determined in the microstructure according to DIN EN 13925 (2003.07) in area% (stated in area%), unless otherwise stated.

The term "flat steel product" in the present text in a rolling process produced steel strips or steel sheets and blanks derived therefrom, blanks and similar products understood, the thickness of each is substantially smaller than their width and length. If we are talking about the "n-value", then this refers to the n-value determined as "n ₁₀ -2o" in accordance with DIN 10275 in the tensile test. The tensile test itself is carried out according to DIN EN ISO 6892-1 (sample form 1).

If we are talking about is the "r-value", then so is the meant as "r _10- 2o" according to DIN 10113 in the tensile certain r value. The tensile test itself is also carried out according to DIN EN ISO 6892-1 (sample form 1).

High-strength, cold-formable steels and steel flat products produced therefrom are used in particular for the production of body components for

Motor vehicles needed. Just there there is a requirement that the sheets from which the components are made, with an optimally low weight are not only well deformed, but also have sufficient strength to make an effective contribution to the stability of the body with low sheet thicknesses.

From US 2017/0114433 A9, a cold-rolled steel sheet is known, which after annealing has TRIP properties and a tensile strength of

at least 1000 MPa, in particular at least 1180 MPa, in one

Total elongation of at least 15%, in particular at least 20% should have. The steel sheet consists of (in wt .-%) C: 0.1 - 0.3%; Mn: 4-10%, Al: 0.05-5%, Si: 0.05-5%; and Nb: 0.008-0.1, balance iron and unavoidable impurities, with Mn contents of 4-7%,

in particular 6 - 7%, Si contents of 0.1 - 1, 1 and Al contents of

0.5-1.6% are particularly preferred. Likewise, an Nb content of 0.02% and C contents of 0.15-0.17% are considered to be particularly favorable. At least 20% of the microstructure of the cold-rolled sheet consists of retained austenite and more than 50% of lathet-type annealed ferrite. At the same time, the retained austenite and the ferrite have an ultrafine grain size of less than 5 pm. In order to achieve the desired structure and strength properties, laboratory scale is a corresponding melted, melted by vacuum induction melt melted into slabs, which has then been pre-rolled to 20 mm thick plates. The plates were kept at a temperature of 1230 ° C for 3 hours to effect homogenization, and then hot rolled in three steps into plates of 4 mm thickness. The hot rolled plates leaving the finish hot roll stand at a final temperature of 900 ° C were then quenched to a coiler temperature of 750 ° C where they were subsequently held for one hour. Then the plates are in the oven

Room temperature has been kept. In this way, the processes should be simulated, which run when a correspondingly produced hot strip is wound into a reel and in the reel on

Room temperature cools down. After annealing, the hot rolled plates were cold rolled to a thickness reduction of 40-50%. The cold-rolled plates have finally passed through a continuous annealing apparatus in which an annealing cycle has been simulated in which the plates are heated to 650-750 ° C., in particular 680-740 ° C., at a heating rate of 10 ° C./s and held there for 180 seconds Temperature are kept to be subsequently cooled to room temperature at a cooling rate of 10 ° C / s.

The advantage of flat steel products of the type described above is their combination due to their comparatively low density, low weight, high strength and good elongation properties. However, the production of such flat steel products on a large industrial scale turns out to be problematic. Thus, for example, shows a high sensitivity to the formation of edge cracks during hot rolling. Also, in practice, it often turns out to be difficult, complex shaped components, as in particular in the field of

Vehicle construction needed, by deep drawing or comparable Forming forming operations where high degrees of deformation can be achieved.

Against the background of the prior art, the object has arisen to create a cold rolled flat steel product satisfying the practical requirements of its usability with high reliability, which can be produced reliably even on a large industrial scale.

In addition, a practical method for the production and at least one advantageous use of such a flat steel product should be specified.

With respect to the flat steel product, the invention has achieved this object in that such a flat steel product according to claim 1 is formed.

A solving the above object according to the invention

Method is specified in claim 12.

In this case, flat steel products according to the invention are particularly suitable for the production of vehicle components, in particular for chassis or body parts of motor vehicles, such as passenger cars or trucks. These parts include, for example, steering components, wheel rims, vehicle chassis components, and the like. However, flat steel products according to the invention may also be used particularly well for the production of devices intended to provide ballistic protection. Because of her good

In addition, flat steel products according to the invention are also particularly suitable for internal or external high-pressure forming processes. For example, components for internal combustion engines, such as camshafts, piston rods and the like, can also be produced from flat steel products according to the invention. Furthermore you can Steel flat products according to the invention in the field of container construction or other applications in which bulky bodies with more complex

Shaping must be produced to be used successfully.

Advantageous embodiments of the invention are in the dependent

Claims are given below and will be like the general one

Invention idea explained in detail.

A flat steel product according to the invention is therefore characterized in that it has a value of at least 0.21 in the cold-rolled state, the flat steel product being made of a steel which consists of (in% by weight)

C: 0.08-0.25%,

 AI: 3 - 5.4%,

 Mn: 6 - 14%,

 B: 0 - 0.1%,

 Cr: 0-2%,

 Si: 0-0.4%,

 P: 0 - 0.1%,

 S: 0 - 0.3%,

 Ta: 0 - 0.5%,

 W: 0 - 0.5%,

 Ni: 0-2%,

 Cu: 0-2%,

 Ca: 0 - 0.15%,

 N: 0-0.02%

 Co: 0 - 2%

 and one or more elements of the group

"Ti, Nb, V, Mo" with the proviso that the sum of the contents of these

Elements is at least 0.05% and at most 1%, and / or one or more elements from the group "Zr, La, Ce, Y" with the proviso that the sum of the contents of these elements is at least 0.05% and at most 0.3%, as well as the balance iron and unavoidable impurities

 consists,

% Mn /% Al> 1, 2 for the ratio% Mn /% AI and for Al _eq =% Al + 0.4 x (% Si) ³ - 3 x (% Si) ² + 8.3 x% Si is 3 <Al _eq <8 with% Mn: respective Mn content of the steel

 % AI: respective Al content of the steel

 % Si: respective Si content of the steel

 the structure of the flat steel product consists of 10 - 60 area austenite and 40 - 90 area% ferrite with an average austenite grain size of 0.85 - 3 pm.

The flat steel product according to the invention in this case has a composition and a structural state, which give it optimized properties for the respective purposes.

Thus, the invention provides a content of carbon ("C") of 0.08 - 0.25 wt .-%, in order to ensure a sufficient amount of austenite in the structure of the flat steel product. Here, the C content is limited to 0.25 wt .-% to the

Tendency to avoid the formation of brittle kappa carbides at the grain boundaries. Such carbides would affect the hot and cold workability of the flat steel products of the present invention. In the content range prescribed according to the invention, the carbon acts as solidifying agent

Mixed crystal formation and increases the stacking fault energy, which in turn

Increase in strength contributes. In addition to the negative effects on ductility, higher C levels would affect weldability. Therefore, the upper limit of the C content according to the invention is limited to 0.25 wt .-%, with C contents of at most 0.22 wt .-%, in particular of not more than 0.19 wt .-% or more preferably of at most 0.17 wt .-% have been found to be particularly favorable in terms of avoiding negative effects of C-content. On the other hand, the positive effects of the presence of C in the flat steel product according to the invention can be utilized in that the C content is at least 0.08% by weight, with contents of at least 0.11% by weight C, in particular at least 0, 13 wt .-% C, set the beneficial effects particularly safe.

Aluminum ("Al") is present in the flat steel product according to the invention in amounts of 3 to 5.4% by weight in order to reduce the density on the one hand and the weight of the flat steel product on the other hand

Increase tensile strength by solid solution hardening. AI also contributes to the formation of the ferrite content in the structure of the flat steel product according to the invention. These favorable effects occur at Al contents of at least 3% by weight, with contents of at least 4% by weight being particularly favorable in this respect. However, in order to avoid negative influences, the Al content of a flat steel product according to the invention is limited to at most 5.4% by weight. Al contents above this limit would lead to a deterioration in cold workability due to formation of intermetallic phases. Al contents of not more than 5.1% by weight have proven to be particularly suitable for achieving good cold workability. In addition, when present at higher levels, Al forms particles that emit nitrogen and carbon embrittlement, reduces thermal conductivity, and lowers the modulus of elasticity.

Manganese ("Mn") is present in the flat steel product of the present invention at levels of 6-14% by weight. Mn contributes to the formation of a sufficient amount of austenite in the structure of the flat steel product and its stability. At the same time, the presence of Mn in the amounts prescribed by the invention improves the thermoformability, weldability and strength of the material

Flat steel product. In this case, Mn acts in the production of the steel from which the flat steel product according to the invention consists, deoxidizing. Too high Mn contents are avoided so as not to impair the corrosion resistance of the flat steel product. In addition, too high Mn contents lead to too high stability of the austenite, so that the TRIP effect is prevented or restricted, which has a negative effect on the formability of the flat steel product. The positive effects of Mn in a flat steel product according to the invention can be used with particular certainty at levels of at least 8% by weight, in particular at least 9% by weight. Negative influences of the presence of Mn with simultaneously optimized cost-benefit ratio can be avoided by limiting the Mn content to at most 12% by weight, in particular at most 11.0% by weight. Mn contents of at most 10.7% by weight have proven to be particularly favorable for achieving good formability.

Boron ("B") may optionally be present in the flat steel product of the present invention to aid in the formation of a fine texture. For this purpose, up to 0.1 wt .-% B may be provided. This results in a positive contribution of B to the properties of a flat steel product according to the invention even at levels of 0.005 wt .-%. The positive influence of B at B contents of less than 0.02% by weight can be used particularly effectively.

Chromium ("Cr") may optionally be added to the flat steel product of the present invention in amounts of up to 2% by weight in order to remove the corrosion and

To improve oxidation resistance. At levels above 2% by weight, Cr carbides may be formed which increase the ductility of the

Steel flat product can affect. The effective influence of Cr at Cr contents of less than 0.8% by weight can be used particularly effectively. The positive effects of Cr can be used particularly reliably in the flat steel product according to the invention if the Cr content is at least 0.05% by weight, in particular at least 0.10% by weight.

Optionally present levels of up to 0.4 wt .-% of silicon ("Si") can be added to the flat steel product according to the invention to the strength and Increase corrosion resistance. At the same time, Si, like Al, reduces the density of the material and contributes to deoxidation. However, excessive Si contents may degrade the ductility and degrade the weldability of the flat steel product of the present invention. These negative effects can be safely avoided by the fact that in a flat steel product according to the invention the Si content is limited to at most 0.3 wt .-%. At the same time, the

Effects of Si in the flat steel product according to the invention already when the Si content is at least 0.05% by weight, in particular at least 0.1% by weight.

Phosphorus ("P") is basically undesirable in the invention

Flat steel product because it causes segregation and affects cold workability, weldability and oxidation resistance. Therefore, the P content is limited to at most 0.1% by weight, especially at most 0.05% by weight.

Sulfur ("S") is also in the flat steel product according to the invention an undesirable accompanying element, since it is too high levels the

Hot workability during hot rolling reduces and deteriorates corrosion resistance.

Tantalum ("Ta") and tungsten ("W") may be added to the invention

Steel flat product to increase strength by carbide addition in amounts of up to 0.5 wt .-% be added. An optimal cost-benefit ratio results at levels of up to 0.1 wt .-%.

Optionally, in amounts of up to 2% by weight of existing nickel ("Ni"), increases the amount and stability of the structure in the present invention

Flat steel product of existing austenite. At the same time, Ni contributes to the strength and toughness of the flat steel product. Likewise, Ni increases the

Corrosion resistance. These advantageous effects can be used in particular when the Ni content of a flat steel product according to the invention at least 0.05 wt .-% is. The positive influence of Ni can be used particularly effectively at Ni contents of less than 1.0% by weight.

The addition of copper ("Cu") at levels of up to 2% by weight improves the corrosion resistance of the flat steel product. Higher Cu contents

However, the hot workability and weldability deteriorate. The positive influence of Cu can be used particularly effectively at Cu contents of less than 0.1% by weight.

Calcium ("Ca") may optionally be added to the steel flat product at levels of up to 0.15% by weight for setting deleterious S levels. Ca is particularly effective in amounts of up to 0.05 wt .-%, which, as far as Ca is ever present, are therefore preferred. Detrimental effects of Ca can thereby be safely avoided that the Ca content is limited to less than 0.01 wt .-%.

Nitrogen ("N") is present in the flat steel product according to the invention in the lowest possible levels in order to avoid the formation of undesirable Al nitrides, which have the mechanical properties and deformability of the

Steel flat product would affect in particular degree. Therefore, the N content of the flat steel product according to the invention is limited to not more than 0.02 wt .-%, in particular 0.01 wt .-%, with practical N contents in the range of 0.001 to 0.008 wt .-% can be found.

Cobalt ("Co") may optionally be added to the flat steel product according to the invention in

Levels of up to 2% by weight can be added to the amount and the

To increase the stability of the austenite present in the structure. At the same time, Co increases the recrystallization temperature. Optimal effects of the presence of Co are obtained when the Co content is limited to at most 1% by weight, with Co contents of less than 0.01% by weight being sufficient in many cases. Antimony ("Sb") affects the properties of the invention

Flat steel product negative and therefore one of the undesirable, but production-related unavoidable impurities. His salary should be as low as possible, at least not like everyone else's here

listed and therefore attributable to the unavoidable impurities elements in the technically ineffective area. As practical

Upper limit, below which the Sb content should be, has proven here 0.002 wt .-%.

Of particular importance are the elements associated with the groups "Ti, Nb, V, Mo" and "Zr, La, Ce, Y". According to the invention, at least one element of at least one of these groups is in the invention

Flat steel product is present to reduce edge stability by the formation of precipitates, i. avoiding the formation of cracks during the

To support hot rolling. In this case, as stated, the elements of the group "Ti, Nb, V, Mo" alone, i. without the presence of an element of the group "Zr, La, Ce, Y", or in combination with at least one of the elements of the group "Zr, La, Ce, Y". Accordingly, the elements of the group "Zr, La, Ce, Y" alone, i. without the presence of any element of the group "Ti, Nb, V, Mo", or in combination with at least one of the elements of the group "Ti, Nb, V, Mo".

In the case that only one element of the group "Ti, Nb, V, Mo" is present in the flat steel product according to the invention, the content of this one element is 0.05-1% by weight. If, on the other hand, two or more elements of the group "Ti, Nb, V, Mo" are present, the sum of the contents is also 0.05-1% by weight.

Particularly favorable influences of the elements of the group "Ti, Nb, V, Mo" arise then, if their content in the case that only one element of this group is present, individually or in the case that two or more elements of this group are present , in total at least 0.08 wt .-% is. An optimal cost-benefit relation can be obtained if in the case that only one element this group is present, individually or in the case that two or more elements of this group are present, in total of the contents of the respectively present elements of the group at most 0.5 wt .-%, in particular at most

0.35 wt .-%, is.

Similarly, in the case that only one element of the group "Zr, La, Ce, Y" is present in the flat steel product of the present invention, its content is 0.05-0.3 wt%. If, on the other hand, two or more elements of the group "Zr, La, Ce, Y" are present, the sum of the contents of these elements is also 0.05-0.3% by weight. Particularly favorable influences of the elements of the group "Zr, La, Ce, Y" arise when their content in the case that only one element of this group is present, individually or in the case that two or more elements of this group are present , in total at least 0.08 wt .-% is. An optimal cost-benefit relation can be obtained if, in the case that only one element of this group is present, individually or in the case that two or more elements of this group are present, in sum the content of the respectively present elements of the group at most 0.2 wt .-%, in particular at most 0.15 wt .-%, is.

In addition to improving edge stability, titanium ("Ti") enhances strength through the formation of Ti carbides and improves r-value. In this case, the positive effect on the edge stability and the strength of Ti results in particular when Nb is present at the same time. The simultaneous presence of Ti and Nb is therefore preferred. The addition of Ti also improves the low temperature toughness and heat resistance of the material. Too high levels of Ti should, however, be avoided in order to avoid negative influences on the ductility and the welding properties. The beneficial effect of Ti can be used especially when the Ti content is at least 0.06 wt .-%. Like Ti, niobium ("Nb"), in addition to improving the edge stability, which results especially when Ti and Nb coexist, produces one

Increasing the strength by the formation of Nb carbides and improves the r-value, which effect is particularly safe when Ti is present at the same time. The addition of Nb also improves the

Low-temperature toughness and the heat resistance of the material. Too high

However, levels of Nb should be avoided to avoid negative effects on ductility and weldability. The

advantageous effect of Nb can be used especially when the Nb content is at least 0.03 wt .-%.

Vanadium ("V") forms carbides and thus, in addition to its positive influence on the edge stability, contributes to the strength of the invention

Steel flat product at. At the same time, the addition of V improves the r value of the flat steel product. The positive effects of V at levels of at least 0.03% by weight can be used particularly reliably.

Also, molybdenum ("Mo") not only improves edge stability, but also contributes to tensile strength and forms with C fine carbides that support the appearance of a fine texture. At too high a content, however, Mo deteriorates the hot and cold formability of the flat steel product of the present invention. The positive effects of Mo can be used especially when the Mo content is at least 0.05 wt .-%.

Improve cerium ("Ce"), lanthanum ("La"), zirconium ("Zr") and yttrium ("Y")

on the one hand, the edge stability. On the other hand, they also act desulphurising and deoxidizing. In addition, they increase the r-value and improve the thermoforming ability. Ce, La, Zr and Y compensate in this way the negative influences that high Al contents on these properties of the

Steel flat product may have. The effects of Ce, La, Zr and Y are the same, so that these elements can be interchanged.

The additional proviso according to which the aluminum equivalent Al _eq formed from the respective Al and Si content must be in the range from 3 to 8% by weight ensures that the contents of the similarly acting alloying elements Al and Si are limited to the extent that the formation of extremely embrittling intermetallic precipitates is prevented. In order to counteract this danger in a particularly reliable manner, the range specified for Al _eq can be restricted according to the invention to not more than 7.6% by weight, in particular not more than 7% by weight or not more than 6.5% by weight. At the same time, the minimum value for Al _eq may be 4.8% by weight.

be raised in order to safely use the positive effects of the simultaneous presence of AI and Si.

According to the invention, the ratio% Mn /% Al of the contents of Mn ("% Mn") and Al ("% Al") should be more than 1.2% by weight, so that, despite the high Al content, a sufficient amount of austenite in the structure of

Flat steel product is achieved.

By the above-explained alloying and the procedural measures explained below it is ensured that the austenite content in the structure of the inventive

Flat steel product 10 - 60 area%. At such levels of austenite, the steel of a flat steel product according to the invention exhibits TRIP properties and the flat steel product has a high n value of

at least 0.21 on.

In addition to the technically unavoidable other structural components, which are present in such small quantities that they have no influence on the properties, there is not austenite Remainder of the structure of the flat steel product according to the invention as a result of the high Al content of ferrite.

Also as a result of the alloying measures and the Fierstellweise invention has an inventive

Flat steel product has an n-value of at least 0.21, wherein

Steel flat products according to the invention regularly achieve n values of at least 0.25, in particular at least 0.26. Flea n values represent high high elongation at break A50

Formability and therefore allow the formation of complex components. Too high n-values should, however, be avoided as this is high

required deformation forces would entail. As a result of their composition and Fierstellung have inventive

Steel flat products n-values, which are regularly not higher than 0.5, in particular not higher than 0.4.

The austenite grain size in the microstructure of an inventive

Flat steel product is on average 0.85 - 3 pm. Too small grains would inhibit the TRIP effect. The desired n-value would not be achieved. Too large grains, however, would result in a large decrease in yield strength and tensile strength. Optimally, the average grain size of the austenite is at least 0.9 pm. It has also proved to be favorable if the maximum size of the austenite grains in the structure of a

Steel flat product according to the invention is limited to 1, 5 pm.

According to a first embodiment of the invention, which contributes to a further improved deformability, in a steel flat product according to the invention in addition to a high Austenitkorngröße a high

Recrystallization in the ferrite grains sought so that they can support the deformation of Austenitkörner. This

Recrystallization degree can with the so-called "Kernal Average Misorientation "(" KAM ") can be quantified. The KAM is a measure of the

Dislocation density. A low KAM in the ferrite thus ultimately means a high deformability of the ferrite. Since the structure of a

austenite and ferrite steel flat product according to the invention

("Duplex texture"), a ferrite low KAM may be low

Compensate austenite grain size. For the out of the respective middle

Grain size KG of austenite and the quotient KG / (KAM 1 5 °) formed at the ferrite "KAM 1 5 ° value" therefore applies according to the invention

KG / (CAM 1 5 °)> 2.7 pm / °. The KAM of the ferrite is hereby measured in longitudinal section as "KAM 1 5 °", whereby the sample was analyzed by EBSD with a

Resolution of 100 nm and then evaluated with a step size of 1 (1st neighbors only) and a cutoff value of 5 °, as in Nafisi S., Szpunar J., Vali H., Ghomashchi R., 2009, Grain misorientation in thixo -billets prepared by melt stirring. Mater Char 60: 938-945).

The process for producing an inventively obtained

cold-rolled steel flat product is designed so that based on the alloying rule of the invention, the desired property profile of the flat steel product is achieved. For this purpose, the process according to the invention comprises the following working steps: a) melting a molten steel consisting of (in% by weight) C: 0.08-0.25%, AI:

 3 - 5.4%, Mn: 6 - 14%, B: 0 - 0.1%, Cr: 0 - 2%, Si: 0 - 0.4%, P: 0 - 0.1%, S: 0 - 0.3%, Ta: 0 - 0.5%, W: 0 - 0.5%, Ni: 0 - 2%, Cu: 0 - 2%, Ca: 0 - 0.15%, N: 0 - 0.02%, Co: 0 - 2%, and one or more elements from the group "Ti, Nb, V, Mo" with the proviso that the sum of the contents of these elements at least 0.05% and is at most 1%, and / or one or more elements of the group

"Zr, La, Ce, Y" with the proviso that the sum of the contents of these elements is at least 0.05% and at most 0.3%, and the remainder iron and unavoidable impurities, where for the ratio% Mn /% AI is% Mn /% Al> 1, 2 and for Al _eq =% Al + 0.4 x (% Si) ³ - 3 x (% Si) ² + 8.3 x% Si, 3 <Al _eq <8 with% Mn: respective Mn content of the steel,% Al: respective Al content of the steel,% Si: respective Si content of the steel; b) casting the molten steel into a precursor, such as a cast billet, a slab, a thin slab or a cast strip; c) holding or heating the precursor at a preheat temperature of 1100-1350 ° C; d) hot rolling the precursor into a hot strip with a

 Hot rolling end temperature, which is 850 - 1050 ° C; e) cooling the hot strip to a coiler temperature 400-900 ° C

 is; f) coiling the hot strip cooled to the coiler temperature into a coil; g) optional: annealing of the hot strip at a hot strip annealing temperature of 700 - 1000 ° C; h) optional: pickling of the hot strip; i) cold rolling the hot strip to a cold rolled steel strip with a total degree of deformation of 25-90%; j) finish annealing the cold rolled steel strip, heating the steel strip to a final annealing temperature and final annealing

- is carried out either as continuous annealing in continuous flow through a continuous annealing furnace in which the cold-rolled steel strip is kept for a period of at least 20 seconds and less than 10 minutes to a final annealing temperature of not less than 950 ° C and not more than 1070 ° C, - or as a bell annealing for a period of 0.5 - 60 h at a

Final annealing temperature is more than 800 ° C and up to 950 ° C.

The steps listed here and explained below are

those which have an influence on the properties of the steel flat product produced according to the invention. It goes without saying that in carrying out the method according to the invention further

Work steps are used. However, these can be carried out in the manner customary in the production of flat steel products by a person skilled in the art, so that it requires no further explanation for this purpose.

Prior to hot rolling, the above in a conventional manner (e.g., via a conventional continuous casting, via a casting mill, via a

Two-roller strip casting) from the invention

composite molten steel produced, which is typically a slab, a thin slab or a cast strip, are heated through. An imperfect, inhomogeneous

Warming would reduce the risk of cracking in the following

continuous hot rolling process. The for the

By heating suitable preheating temperatures are 1100 - 1300 ° C, wherein preheating temperatures of at least 1150 ° C have proven to be particularly reliable in practice. By the

Preheat temperature is limited to at most 1250 ° C, can negatively impact the preheating, such as too doughy consistency of the

Pre-product and a concomitant tendency for sticking during hot rolling counteracted.

Hot rolling of the precursor to a hot strip can be done in

Conventional way to do this in practice

stationary hot rolling mill. The only important thing is that the Hot strip at the end of hot rolling still has a hot rolling end temperature, which is 850 - 1050 ° C. Below 850 ° C

Hot rolling temperatures would require such high hot rolling forces that the desired degree of deformation can not be achieved on conventional hot rolling stands. Optimal hot rolling temperatures are therefore in the range of 900 - 1050 ° C.

Starting from the hot rolling end temperature, the obtained

If necessary, hot tapes on the conventional way

According to the invention predetermined reel temperature of 400 - 900 ° C cooled, with which they are then coiled to form a coil. The minimum coiler temperature of 400 ° C is due to the poor thermal

Conductivity of the steel of a flat steel product according to the invention required because otherwise would result in high temperature gradients in the steel flat product to tensions and a concomitant poor flatness of the hot strip. Too fast cooling in the cooling section could stop the recrystallization processes that begin with the end of hot rolling. Optionally, however, the coil wound to the hot strip can be cooled by means of a coil shower to shorten the cooling time and positively influence the formation of scale.

To complete the recrystallization and one for the

subsequent cold rolling to produce optimum state, the hot strip after cooling in the coil can optionally undergo an annealing, in which it is maintained over a sufficient for the complete recrystallization period at a temperature of 700-1000 ° C, especially 700-900 ° C. Preferably, the hot strip annealing is optionally carried out as a bell annealing, in which case the annealing time typically takes 0.5 to 60 hours. To clean its surface, the hot strip may be subjected to a pickling treatment prior to cold rolling. The in the course of

Production process by oxygen-affine elements caused by scale formation on the hot strip surface can be reduced by an extended residence time of the hot strip in the pickling medium. The Hotbandbeizung can be carried out with different pickling media such as hydrochloric acid.

The cold-rolling of the hot-rolled strip to a cold-rolled strip is carried out with a Gesamtumformgrad 25-90%, in particular at least 40% or at least 50%. The invention

provided minimum degree of deformation is required to initiate the recrystallization in particular of the ferrite contained in the structure of the steel flat product in the final annealing. Too high degrees of deformation should be avoided, as these too large

Hardening and concomitantly lead to the risk of tape breaks.

About the final annealing, the mechanical

Properties of the flat steel product according to the invention decisively influenced. The final annealing can be completed in a continuous flow through a conventional continuous furnace or as batch annealing in batch mode.

In the case that the final annealing is completed in the run, the cold-rolled steel flat product with a typically 1 - 100 K / s, in particular 10 - 80 K / s or 20 - 50 K / s, heating rate amounts to a final annealing temperature, which is at least 950 ° C and at most 1070 ° C, heated. Too rapid heating may adversely affect the homogeneity of the heating and, consequently, the homogeneous distribution of properties of the flat steel product. The final annealing temperature is chosen so that the necessary

Austenitkorngröße sets, which is a prerequisite for the TRIP properties and the n value of the flat steel product according to the invention. The necessary austenitic grain size can be adjusted particularly safely if the final annealing temperature is at least 970 ° C.

Optimally practical final annealing temperatures are in the range of 1000 - 1070 ° C. By setting such high

Final annealing temperatures can produce flat steel products according to the invention having austenite grain sizes of 0.9-1.5 pm and a n-value lying regularly above 0.25, for example above 0.26.

The holding times at the final annealing temperature in the continuous annealing furnace amount to no more than 10 minutes, in particular not more than 5 minutes or 3 minutes, depending on the level of the final annealing temperature, with higher continuous annealing temperatures allowing shorter holding times and minimum holding times of at least 20 seconds being practical ,

In the case that the final annealing is carried out as a bell annealing, the under the hood placed in the coil is cold rolled with a

Heating rate of 0.001 - 0.5 K / s, in particular 0.002 - 0.5 K / s or

0.008 - 0.5 K / s, heated to the final annealing temperature, which is more than 800 ° C, in particular more than 850 ° C, respectively. There should be a

Final annealing temperature of 950 ° C should not be exceeded

to avoid excessive grain growth. The annealing times after reaching the final annealing temperature are in the range of 0.5 - 60 h,

especially 1 - 30 h. In this way, flat steel products according to the invention with an n-value of at least 0.21 and

Austenite grain sizes of 0.85 - 3 pm are produced particularly reliable. To protect against corrosion and external influences, the flat steel product according to the invention can be provided with a protective coating. This can be applied, for example, in a conventional manner by means of coating systems available in practice as a zinc or aluminum-based coating.

The invention will be explained in more detail by means of exemplary embodiments.

To test the effects of the invention, eight melts A - H were prepared, the wet-chemically determined analyzes of which are given in Table 1. The analysis data of the individual elements relate in each case to the determined contents in% by weight. If this is entered in the respective table field, this means that the content of the respective element was below the respective detection limit and the element concerned was consequently ineffective with regard to the properties.

(Note: The detection limits are 0.005 wt% for P and Ti, 0.001 wt% for Cr, Co, S, and Ca respectively, and 0.01 wt% for V, Mo, and Ni, respectively. for Cu and Nb each at 0.02 wt%, for B at 0.0004 wt% and for Ce, La, Y, Zr, As and Sn each at 0.002 wt%). Elements that were present at such low levels are the inevitable as are the unlisted elements

Allocate impurities. These include, for example, contents of As, Sn, Mg and H. The sums of the microalloying elements Ti, Nb, V, Mo, the sum of the rare earth metals Ce, La, Y, Zr, the ratio of Mn to Al and the Al Equivalent individual melts are given in Table 2.

Of melts A - H, melts A and B are not

according to the invention, since they are provided in accordance with the invention Do not meet requirements for the presence of at least one element from the groups "Ti, Nb, V, Mo" and "Zr, La, Ce, Y".

For 27 experiments 1 - 27, the melts A - H were cast in a conventional manner to blocks, which then at a

Preheat temperature VWT have been through a period VWD durchwarmt.

After being soaked, the blocks have also been conventionally rolled into slabs in a conventional hot rolling mill. The slabs were rolled in a hot rolling mill to hot strip with a thickness of 2.5 - 3.0 mm. The hot rolling was finished with a hot rolling end temperature WET.

After hot rolling, the hot strips obtained in this case were cooled in air in each case to a reel temperature HT at which they have been coiled to form a coil.

After cooling in the coil, an evaluation of the strip edges for the formation of cracks was carried out on each of the hot strips obtained in Runs 1-27. Here are as "strong" of

Edge cracks have been classified as such hot bands where regular indentations larger than 15 mm have been found. Hot tapes affected by "edge cracks" are classified as having regular notches with a size of 2 - 15 mm. The rating "none" is in the

Hot tapes were made in which maximum notches were present with a size of less than 2 mm.

Some of the hot strips were then subjected to a hot strip annealing, which has been carried out as a bell annealing with an annealing temperature of 850 ° C and an annealing time of 6 hours. The annealed as well as the unannealed hot tapes have been cold rolled into cold rolled steel strip in a conventional cold rolling machine with a total cold forming degree KGW.

Finally, the cold-rolled steel strips obtained are in continuous ("Konti") in a continuous annealing furnace or batchwise in one

Annealing annealing furnace ("hood") has been final annealed. They are each with an average heating rate HR on the respective

Final annealing temperature Tsg have been heated, in which they have been held for a duration tsg.

The melt composition "steel" of the steel strips processed in each of experiments 1 to 27 which were used in experiments 1 to 27

applied parameters preheating temperature VWT, preheating VWD, hot strip thickness WB, hot rolling end temperature WET, reel temperature HT, the result of the assessment of the edge cracks on each hot strip, the indication of whether completed in the above manner

Hot-rolled annealing, the total cold forming degree KGW, the type of final annealing, the heat-up rate HR of the final annealing, the final annealing temperature Tsg and the final annealing time tsg are given in Table 3a and Table 3b.

In Table 4a and Table 4b, as far as detected, the upper and lower yield strengths ReH and ReL determined on the obtained cold-rolled and finally annealed steel strips, the yield strength Rp0.2, are

Tensile strength Rm, the elongation at break A50, the n value n _10-2 o, the r value r _10-2 o, the austenite grain size KG, the KAM value determined at a step size of 100 nm and a deposition value of 5 °, and quotient KG / KAM indicated. The yield strengths ReH and ReL, the yield strength Rp0.2, the tensile strength Rm and the elongation at break A50 have been determined according to DIN EN ISO 6892-1: 2009 on cold-rolled strip in the transverse direction. to Determination of the austenite grain size KG was determined by means of EBSD (Electron Back Scattering Diffraction) of the mean circular equivalent grain diameter. For the calculation of the grains in the EBSD representation, a tolerance angle of 5 ° was chosen for a minimum grain size of five contiguous neighboring measuring points with a step size of 0.15 μm. The n _10-2 o and the r ₁₀ 2o value and the KAM value have been determined in the manner already explained above. Unrecorded values are indicated in Table 3 by.

Examples 10, 11, 15, 16, 20, 23 were finally annealed in a continuous furnace with a final annealing temperature of 830 ° C. in each case

outside of for a continuous annealing

According to the invention predetermined temperature range of 950 - 1070 ° C was. The steel flat products produced in Examples 10, 11, 15, 16, 20, 23 accordingly had very low n values, which are below the minimum value of 0.21 provided according to the invention.

The experiments prove that reliably cold-rolled in the case of the alloy according to the invention and the method of manufacture according to the invention

Produce flat steel products that show at best slight edge cracking and thereby have a combination of mechanical properties that make them ideal for uses in which components are formed from the flat steel products at high degrees of deformation.

 Remaining iron and unavoidable impurities

Information on alloy contents in% by weight ^* ) not according to the invention

Table 1

O

Al _eq =% Al + 0.4 x (% Si) ³ - 3 x (% Si) ² + 8.3 x% Si

% Mn = respective Mn content,

 % AI = respective Al content,

 % Si = respective Si content

^* ) not according to the invention

Table 2

 n

H

bo oo

O

 O

IΌ

00 n

 H

 bo o o

Table 3a

O

 O

IΌ

CD

 Table 3b

n

H

bo oo

O

 n

H

 Table 4a means that the corresponding value has not been determined.

os

Table 4b indicates that the corresponding value has not been determined.

Claims

PATENT CLAIMS E

1. Cold rolled flat steel product containing a minimum of 0.21

Value and that is made of a steel made of (in% by weight)

C: 0.08-0.25%,

 AI: 3 - 5.4%,

 Mn: 6 - 14%,

 B: 0 - 0.1%,

 Cr: 0-2%,

 Si: 0-0.4%,

 P: 0 - 0.1%,

 S: 0 - 0.3%,

 Ta: 0 - 0.5%,

 W: 0 - 0.5%,

 Ni: 0-2%,

 Cu: 0-2%,

 Ca: 0 - 0.15%,

 N: 0-0.02%

 Co: 0 - 2%

 and one or more elements from the group "Ti, Nb, V, Mo", with the proviso that the sum of the contents of these elements is at least 0.05% and at most 1%, and / or one or more elements the group "Zr, La, Ce, Y" with the proviso that the sum of the contents of these elements is at least 0.05% and at most 0.3%, as well as the balance iron and unavoidable impurities

 consists,

where for the ratio% Mn /% AI applies % Mn /% AI> 1, 2

and for Al _eq =% Al + 0.4 x (% Si) ³ - 3 x (% Si) ² + 8.3 x% Si

3 <Al _eq <8

 with% Mn: respective Mn content of the steel

 % AI: respective Al content of the steel

 % Si: respective Si content of the steel

 the structure of the flat steel product consists of austenite at 10-60 area% and ferrite at 40-90 area% with an austenite mean grain size of 0.85-3 pm.

2. flat steel product according to claim 1, characterized in that for the quotient KG / (KAM 15 °) from the respective mean grain size KG of the austenite and the ferrite on the determined KAM 15 ° value KG / (KAM 15 °)> 2, 7 pm / °.

3. Flat steel product according to one of the preceding claims, characterized in that its n-value is at least 0.25.

4. Flat steel product according to one of the preceding claims, characterized in that the mean grain size of the austenite is 0.9 - 1.5 pm.

5. Flat steel product according to one of the preceding claims, characterized in that its Al content is 4 - 5.4 wt .-%.

6. Flat steel product according to one of the preceding claims, characterized in that its C content is 0.11 - 0.19 wt .-%.

7. Flat steel product according to one of the preceding claims, characterized in that its Mn content is 8-12 wt .-%.

8. Flat steel product according to one of the preceding claims, characterized in that its Si content is at least 0.01 wt .-%.

9. Flat steel product according to one of the preceding claims, characterized in that for Al _eq , Al _eq <7.

10. Flat steel product according to one of the preceding claims, characterized in that its tensile strength Rm at most

 1050 MPa, in particular at most 950 MPa.

11. Use of one according to one of the preceding claims

 obtained cold-rolled steel flat product for the production of vehicle parts.

12. A method for producing a according to any one of claims 1-10

a cold molten steel flat product comprising the following steps: a) melting a molten steel consisting of (in% by weight) C: 0.08-0.25%, AI: 3-5.4%, Mn: 6-14%, B: 0 - 0.1%, Cr: 0 - 2%, Si: 0 - 0.4%, P: 0 - 0.1%, S: 0 - 0.3%, Ta: 0 - 0.5 %, W: 0-0.5%, Ni: 0-2%, Cu: 0-2%, Ca: 0-0.15%, N: 0-0.02%, Co: 0-2%, and one or more elements from the group "Ti, Nb, V, Mo" with the proviso that the sum of the contents of these elements is at least 0.05% and at most 1%, or one or more elements Elements from the group "Zr, La, Ce, Y" with the proviso that the sum of the contents of these elements is at least 0.05% and at most 0.3%, and the remainder iron and unavoidable

 Impurities is, where for the ratio% Mn /% AI applies

% Mn /% Al> 1, 2 and for Al _eq =% Al + 0.4 x (% Si) ³ - 3 x (% Si) ² + 8.3 x% Si 3 <Al _eq <8 with% Mn: respective Mn content of the steel,% Al: respective Al content of the steel,% Si: respective Si content of the steel; b) casting the molten steel into a precursor, such as a cast billet, a slab, a thin slab or a cast strip; c) holding or heating the precursor at a preheat temperature of 1100-1350 ° C; d) hot rolling the precursor into a hot strip with a

 Hot rolling end temperature, which is 850 - 1050 ° C; e) cooling the hot strip to a coiler temperature that is 400-900 ° C; f) coiling the hot strip cooled to the coiler temperature into a coil; g) optional: annealing of the hot strip at a hot strip annealing temperature of 700 - 1000 ° C; h) optional: pickling of the hot strip; i) cold rolling the hot strip to a cold rolled steel strip with a total degree of deformation of 25-90%; j) final annealing of the cold rolled steel strip, the final annealing

- Is completed either as a continuous annealing in a continuous pass through a continuous annealing furnace, in which the cold-rolled Steel strip is maintained for a period of at least 20 seconds and less than 10 minutes to a final annealing temperature which is at least 950 ° C and not more than 1070 ° C,

- or is carried out as a continuous annealing over a period of 0.5 to 60 hours at a final annealing temperature exceeding 800 ° C and up to 950 ° C.

13. The method according to claim 12, characterized in that the hot rolling end temperature is at least 900 ° C.

14. The method according to any one of claims 12 to 13, d a d u r c h

 characterized in that in the case that the final annealing is carried out as a continuous annealing, the final annealing temperature is at least 1000 ° C, or in the case that the final annealing is performed as a bulb annealing, more than 850 ° C.

15. The method according to any one of claims 12 to 14, d a d u r c h

 characterized in that the flanging temperature is 600 - 850 ° C.