WO2020007459A1

WO2020007459A1 - Galvanised cold-rolled sheet with homogeneous material properties

Info

Publication number: WO2020007459A1
Application number: PCT/EP2018/068091
Authority: WO
Inventors: Robert YANIK; Bastian Schöntaube; Yavuz Dogan; Thomas Brixius
Original assignee: Thyssenkrupp Steel Europe Ag; Thyssenkrupp Ag
Priority date: 2018-07-04
Filing date: 2018-07-04
Publication date: 2020-01-09
Also published as: WO2020007594A1; EP3752652A1

Abstract

The present invention relates to a method for producing a flat steel product having a coating that protects against corrosion, a corresponding flat steel product, a component obtained therefrom by means of forming, and the use of same in the automotive sector, more particularly for utility vehicles, more particularly for trucks, construction machines and earth-moving vehicles, in the industrial sector, for example as housings or telescopic rails, in the construction sector, for example as a facade element, for domestic appliances, in the energy sector or in shipbuilding.

Description

Galvanized sheet steel with homogeneous material properties

Technical field

The present invention relates to a method for producing a flat steel product with a protective coating against corrosion, a corresponding flat steel product, a component obtained therefrom by deformation and its use in the automotive sector, in particular for commercial vehicles, in particular trucks, construction machines and earth moving vehicles, in the industrial sector, for example as Housing or telescope rails, in the construction sector, for example as facade elements, for household appliances, in the energy sector, in shipbuilding.

Technical background

Methods for coating flat steel products with a corrosion-protective coating based on Zn or Zn and magnesium are known per se to the person skilled in the art.

The document US 2015/292072 A1 discloses a method for producing a flat steel product with a coating which protects against corrosion, wherein after the uncoated flat steel product has been immersed in a corresponding melt bath, the stripped liquid metal is stripped off using a stripping nozzle, in order to set the desired layer thickness this is arranged under very specific geometric conditions for the flat steel product.

US 2016/339491 A1 discloses a method for producing a zinc-coated sheet. For this purpose, a cold-rolled steel strip is rolled with a textured roller and then electrolytically coated with a zinc layer that protects against corrosion.

US 2012/0107636 A1 discloses a method for coating a flat steel product with a coating which protects against corrosion, in particular a coating containing Zn. After the actual coating process, excess liquid metal is removed in a stripping device with a certain geometry.

In the case of flat steel products, a deformation stress can lead to an undesirable change in the surface topography, which affects the appearance of the product after painting. Under manufacturing conditions not according to the invention, steels with BHO or BH2 values, measured according to SEW094, greater than 5 MPa are affected.

A common test condition for recording the surface change after forming is a biaxial stretching with 3.5% or 5% elongation. Usually the ripple is only measured in the profile section (see SEP 1941). However, various measuring methods, such as confocal light microscopy or laser scanning, are also suitable for capturing the surface not only along a line, but also in three dimensions. The basis of the invention is the knowledge that a ripple characteristic value, which is determined from such a flat topography measurement, can reflect the appearance of the surface after painting more meaningfully than a simple profile characteristic value. Profile filtering takes place only in one spatial direction. At a Area measurement, the folding operation is possible in both lateral directions. This is more realistic because the counterpart to filtering, the lacquer layer, does not cover the roughness in a linear manner, but rather over a large area.

To determine the areal ripple value SWg, the measuring surface must have a width of at least 0.5 mm and a length of at least 25 mm. The lateral resolution of the measuring points must be at least 10 pm. The flea data must be aligned in the area.

The aligned data are low-pass filtered using a surface filter in accordance with DIN EN ISO 16610-61: 2012. The weight function of the area filter has the equation of a rotationally symmetrical Gaussian function with a cutoff wavelength lw of 0.6 mm. A profile or several profiles are extracted from the topography measurement data along the measurement direction, and the profile or the profiles is / are high-pass filtered in accordance with the DIN EN ISO 11562 standard with a cutoff wavelength of 5 mm. From the flea data, the square mean or square mean QMW (root mean sguare RMS) is calculated and the SWg value is thus obtained.

In the wake of the current trend in the automotive industry to apply thinner and partly filler-free painting systems, a deformation-related deterioration in the waviness has a significant impact on the paint appearance. The paint appearance marks an important purchase criterion when purchasing a new car.

The object of the present invention is to provide a method for the manufacture of flat steel products provided with a protective coating against corrosion, with which it can be ensured that corresponding flat steel products are obtained which, in a reshaping provided in the further process, do not cause any significant change which would interfere with the paint appearance experienced in the surface topography.

These tasks are solved by the method according to the invention for the production of a flat steel product with a coating protecting against corrosion, at least comprising the following steps:

(A) providing a flat steel product,

(B) optionally cleaning the flat steel product from step (A),

(C) recrystallizing annealing of the flat steel product from step (A) or (B),

(D) applying a protective coating against corrosion to the flat steel product from step (C),

(E) skin pass the flat steel product from step (D) and

(F) reeling the coated steel flat product from step (D), step (C) being carried out in such a way that the process parameters annealing temperature in ° C, annealing duration in s and dew point in ° C within a three-dimensional coordinate system with the corner points A (870/190 / 15), B (870/190 / -25), C (830/190/15), D (830/190 / -25), E (870/381/0), F (870/428/0) , G (870/490 / -8.5), FK870 / 490 / -25), 1 (830/381/0), J (830/423/0), K (830/490 / -8.5) , L (830/490 / -25), whereby the annealing temperature in ° C is represented by the x value, the annealing time in s by the y value and the dew point in ° C by the z value.

The objects are further achieved by the flat steel product produced according to the invention and its use. The deformation-related topography changes, which are noticeable in the areal ripple value or after painting, result in cold-rolled thin sheet with a BH2 value according to SEW094 of more than 5 MPa from the usual manufacturing conditions, which lead to anisotropy of the material via the sheet metal cross-section in combination with a pronounced elongation limit, which then leads to flow figures on the surface. The material anisotropy along the sheet cross-section is characterized by an inhomogeneous distribution of the free carbon. Elongation at stretch is caused by the interposition atoms dissolved in the structure, including the free carbon.

Elongation at yield point leads to the formation of flow figures on the component surface and is therefore undesirable for the purposes sought in the present invention application. In order to reduce the latter, the free carbon content can be reduced, for example, by means of suitable measures, which would, however, also be associated with a disadvantageous reduction in the BH2 value. In order to avoid this conflict of goals, instead of an absolute reduction in the free C content, this can be redistributed over the sheet cross-section in such a way that there is no significant reduction in the BH2 value, but stretching limit stretching and thus flow figures on the surface can be avoided. In addition, the material anisotropy can be reduced in this way via the sheet metal cross section, which likewise leads to favorable long-wave properties of the surface.

It has been found according to the invention that in order to meet both claims, i.e. Bake hardening and homogeneous forming behavior, a very specifically selected combination of annealing temperature, annealing time and dew point must be used in the recrystallizing annealing step.

A redistribution of the carbon content along the sheet thickness can be achieved by the procedure according to the invention, which leads to a homogeneous carbon distribution which corresponds to a low material anisotropy. In addition, the combination of annealing temperature, annealing duration and dew point according to the invention makes it possible for the yield point elongation to be influenced positively, which contributes to the avoidance of flow figures during subsequent forming. The yield point expansion results from the free carbon atoms in the material, which prevent the sliding of dislocations when deformation begins. These handicaps go hand in hand with the constant dislodging and sliding (stick-slip effect) of the dislocations, which become visible on the surface of the material in the form of flow figures and increase the boredom.

In the context of the present invention, the material is decarburized in step (C) of the process by a targeted redistribution of the interstitially dissolved carbon atoms. If, for example, a too high dew point is set in the furnace in step (C), a lot of carbon is removed from the edge area of the material, which leads to an extreme concentration gradient between the core and the surface and, as a result, to a pronounced material anisotropy, which leads to an inhomogeneous Flow of the material along the sheet metal section is responsible during the forming process (eggshell effect). However, if the dew point in step (C) is chosen too dry, either no or too little carbon is removed from the edge area, and the yield point elongation is pronounced, which leads to flow figures during the forming. According to the invention, the dew point must be selected in combination with the annealing duration and annealing temperature so that complete decarburization is prevented and at the same time no further carbon moves up from the core area. According to the invention, this allows an excessive concentration gradient and a material anisotropy associated therewith to be avoided. However, according to the invention, so much carbon has to be extracted from the material that the surface is gently decarburized in order to avoid the extent of the yield point elongation, without setting a clear difference in concentration between the core and surface of the material. The method according to the invention, in particular step (C) according to the invention, makes it possible to maintain a previously set topography about a uniform flow of the material on the surface during the forming.

The individual steps of the method according to the present invention are described in detail below. The process according to the invention can be carried out batchwise or continuously. In a preferred embodiment, it is carried out continuously.

Step (A) of the method according to the invention comprises providing a flat steel product.

According to the invention, in step (A) of the method it is generally possible to use any flat steel product known to the person skilled in the art which can or should be provided with a coating which protects against corrosion. According to the invention, a flat steel product is understood to be a sheet, a plate or a steel strip. According to the invention, a steel strip is used before.

The flat steel product used in step (A) of the method according to the invention can be a hot strip or a cold strip. A cold strip is preferably used according to the invention.

The flat steel product can generally be used in all thicknesses known to the person skilled in the art, for example 0.2 to 1.2 mm, preferably 0.5 to 0.9 mm. If a steel strip is used according to the invention, it preferably has a width of 500 to 2500 mm, particularly preferably 800 to 2000 mm.

The steel present in the flat steel product used according to the invention can generally have any composition. The steel present in the flat steel product used according to the invention preferably has a composition which enables a BFI2 value of> 5 MPa. According to the invention, a flat steel product is particularly preferably used, comprising a steel containing, in addition to Fe and unavoidable impurities (all data in% by weight)

0.00 to 0.3 C,

0.00 to 1.50 Si,

0.01 to 4.00 Mn,

0.00 to 0.10 P,

0.00 to 0.02 S,

0.001 to 2.20 AI,

up to 0.2 Ti + Nb,

up to 1.50 Cr + Mo,

up to 0.25 V,

up to 0.01 N,

0.00 to 0.20 Ni,

up to 0.01 B and up to 0.01 approx

contains.

The optional step (B) of the method according to the invention comprises cleaning the flat steel product from step (A).

Step (B) of the process according to the invention can generally be carried out by all processes known to the person skilled in the art. The cleaning can be done mechanically by brushing, alkaline by appropriate cleaning agents, for example containing surfactants and / or defoamers, and / or electrolytically, for example by alternately switching the strip as cathode and anode. The three methods mentioned can be used individually or usually in combination. If necessary, thermal cleaning can also be carried out on an open flame.

If necessary, the flat steel product can be dried after cleaning, for example at elevated temperature and / or using air nozzles.

Step (C) of the method according to the invention comprises recrystallizing annealing of the flat steel product from step (A) or (B), step (C) being carried out in such a way that the process parameters annealing temperature in ° C, annealing duration in s and dew point in ° C within one three-dimensional coordinate system with the corner points A (870/190/15), B (870/190 / -25), C (830/190/15), D (830/190 / -25), E (870/381/0 ), K870 / 381 / -25), N (830/381 / -25), F (870/428/0), G (870/490 / 8.5), H (870/490 / -25), K (830/423/0), L (830/490 / -8.5), M (830/490 / -25), the annealing temperature in ° C by the x value, the annealing time in s by the y value and the dew point in ° C can be represented by the z value.

According to the invention, the designation A (870/190/15) means, for example, a point in a three-dimensional coordinate system with the annealing temperature in ° C on the x-axis, the annealing duration in s on the y-axis and the dew point in ° C on the z- Axis. The point therefore means, for example, that step (C) of the process according to the invention takes place at an annealing temperature of 870 ° C. for 190 s at a dew point of 15 ° C. According to the invention, the recrystallizing annealing in step (C) is carried out under conditions which lie within the three-dimensional space spanned by the corner points A to M. If step (C) is carried out under these conditions, the technical advantages mentioned above are obtained. If step (C) is carried out under conditions which lie outside this three-dimensional space, the technical advantages mentioned above are not obtained.

The technical advantages according to the invention are particularly pronounced if step (C) of the process is carried out in such a way that the process parameters annealing temperature in ° C, annealing duration in s and dew point in ° C within a three-dimensional coordinate system with the corner points E (870/381/0 ), F (870/428/0), G (870/490 / -8.5), H (870/490 / -25), K870 / 381 / -25), J (830/381/0), K (830/423/0), L (830/490 / -8.5), M (830/490 / -25), N (830/381 / -25).

The present invention therefore preferably relates to the process according to the invention, the process parameters annealing temperature in ° C, annealing time in s and dew point in ° C within a three-dimensional coordinate natensystems with the corner points E (870/381/0), F (870/428/0), G (870/490 / -8.5), H (870/490 / -25), 1 (870/381 / - 25), J (830/381/0), K (830/423/0), L (830/490 / -8.5), M (830/490 / -25), N (830/381 / -25).

It is further preferred according to the invention that step (C) is not carried out in such a way that the process parameters annealing temperature in ° C, annealing duration in s and dew point in ° C within a three-dimensional coordinate system with the corner points 0 (870/434/0), P (870/490/0), Q (870/490 / -8), R (830/428/0), S (830/490/0), K830 / 490 / -8). If the method according to the invention were carried out in these areas, the above-mentioned technical advantages would not be obtained.

Step (C) of the method according to the invention can generally be carried out in all devices known to the person skilled in the art, in which it is possible to control the annealing temperature, annealing duration and dew point so that these values lie in the ranges according to the invention. Preferred devices for step (C) of the process according to the invention are preferably continuously operating furnaces, for example a continuous annealing furnace of an FBA (fire coating system) or continuous annealing, or non-continuously operating furnaces, for example by bell annealing.

Step (D) of the method according to the invention comprises the application of a protective coating against corrosion to the flat steel product from step (C). Processes for applying coatings protecting against corrosion are known per se to the person skilled in the art. A coating containing zinc is preferably applied as a protective coating against corrosion. A zinc-containing coating is preferably applied by a hot-melt dipping method known to the person skilled in the art or by electrolytic deposition. Methods for hot dip coating are described, for example, in US 2015/292072 A1, US 2016/339491 A1, US 2012/0107636 A1 and in our own application DE 10 2017 216 572.3. Electrolytic processes for the deposition of a zinc-containing layer are also known to the person skilled in the art and are described, for example, in WO 2015/114405.

According to the invention, a coating protecting against corrosion is preferably applied, containing 0.1 to 2.0% by weight of Al and optionally 0.1 to 3% by weight of Mg, the rest being Zn and inevitable impurities. The corrosion-protecting coating is further preferably applied by hot dip coating.

The present invention therefore preferably relates to the process according to the invention, step (D) being carried out by hot-dip coating in a melt bath, containing 0.1 to 2.0% by weight of Al and optionally 0.1 to 3% by weight of Mg, the remainder being Zn and inevitable impurities.

After the flat steel product has been coated with the coating protecting against corrosion, the desired layer thickness or the desired coating weight is set by methods known to the person skilled in the art, for example using scraping nozzles. According to the invention, the protective coating against corrosion is preferably present in a coating weight of 20 to 100 g / m ² , preferably 30 to 80 g / m ² , in each case on each side of the flat steel product. The applied coatings protecting against corrosion can optionally be diffusion annealed, for example at 450 to 550 ° C., so that an Fe content of 0.1 to 15% by weight, preferably 4 to 10% by weight, is found in the corrosion protection protective coating.

The present invention therefore preferably relates to the method according to the invention, the coating protecting against corrosion being diffusion annealed.

Step (E) of the method according to the invention comprises the dressing of the flat steel product from step (D).

In principle, step (E) of the method according to the invention can be carried out by all methods known to the person skilled in the art. Methods known to the person skilled in the art which can be used here are, for example

• SBT (shot blast texturing), the roller is mechanically bombarded, i.e. particles are knocked out of the roller;

• EDT (electrical discharge texturing), here oscillating electrodes are attached to the rotating roller, the roller surface melts locally due to the current flow, when the current is switched off gas bubbles that have formed on the surface implode and material is thrown out;

• LT (Laser Texturing), here a precise laser melts the roller surface locally, melt is expelled by pressure of the plasma or inert gas;

• EBT (Electron Beam Texturing) similar to the LT process, but with an electron beam instead of a laser beam;

• ECD (Electro Chemical Deposition), here no material is driven out, but controlled application of material by electrolytic flart chrome plating of the roller (as cathode), control of the voltage between the anode cage and roller results in a structured application.

EDT-textured rollers are preferably used according to the invention.

The roughnesses Ra of the work rolls used are preferably less than or equal to 4.0 pm, particularly preferably less than or equal to 2.7 pm, very particularly preferably less than or equal to 2.2 pm. According to the invention, the work roll roughness is preferably at least 0.5 pm.

Step (F) of the method according to the invention comprises coiling the coated steel flat product from step (E). In step (F) of the method according to the invention, the flat steel product obtained from step (E) is provided with a corrosion-protective coating, i.e. wound into a coil. The reeling in step (F) of the method according to the invention can be carried out by all methods known to the person skilled in the art.

The flat steel product obtained by the process according to the invention comprising at least steps (A), (B), (C), (D), (E) and (F) is particularly suitable on account of the advantages described above, for further processing by forming into components , which are used, for example, as the outer skin of vehicles, in particular automobiles. The present invention therefore further relates to a method for producing a component, comprising at least the following steps:

(G) providing a flat steel product with a coating protecting against corrosion by the method according to the invention, and

(H) reshaping the steel flat product from step (G) to obtain the component.

Step (G) of the method according to the invention comprises providing a flat steel product with a coating protecting against corrosion by the method according to the invention. This method according to the invention comprises at least steps (A), (B), (C), (D), (E) and (F) as described above.

From step (F) of the method according to the invention, the flat steel product emerges in coiled form as a coil. It is therefore preferred according to the invention to unroll the flat steel product obtained from step (F) before step (G) and, if necessary, to smooth and / or clean it. For example, after unrolling, the flat steel product passes through a set of processor straightening rollers, in particular for leveling any unevenness, is then cut into boards of the desired shape and, if necessary, treated with methods known to the person skilled in the art, for example oiling, cleaning, etc.

Step (H) of the method according to the invention comprises shaping the flat steel product from step (G) in order to obtain the component. Appropriate methods are known per se to the person skilled in the art. Step (G) of the method according to the invention is preferably carried out by cold working. For this purpose, the flat steel product, which is preferably obtained as a steel strip, is first cut or punched into corresponding sheets or blanks. These sheets or blanks are then placed in an appropriate forming tool and shaped under pressure.

The present invention also relates to a flat steel product provided with a corrosion-protecting coating, produced by the method according to the invention, comprising at least steps (A), (B), (C), (D) and (E). The process according to the invention makes it possible to produce a flat steel product which, owing to the recrystallizing annealing according to the invention in step (C), has a particularly good surface condition in the deformed state under specially selected conditions. This is shown in particular by an advantageous ripple characteristic value SWg.

The present invention preferably relates to the flat steel product according to the invention, the coating protecting against corrosion not only containing Zn and unavoidable impurities, but also containing 0.1 to 2.0% by weight of Al and optionally 0.1 to 3% by weight of Mg.

The present invention further relates to a flat steel product provided with a protective coating against corrosion, the flat steel product having a carbon distribution according to the following formula (I)

(0.0187 + 0.00957fc) x ³ + (0.4335 - 0.1559fe)% ² + (0.2563 + 0.181k) x + 1

fixed) (I),

(0.00879 + 0.004546fc) x ² + (0.00534 + 0.02095fc) x where f (x), x and k have the following meanings: f (x) relative amount of carbon, based on the original amount of carbon, at a normalized depth x, x normalized depth in the flat steel product, and

k less than 0.768 f (x) in formula (I) means the carbon content, based on the original carbon content, at a normalized depth x. If, for example, there is carbon in an amount of 50 ppm before the annealing step (C) at a standardized depth x, and after the annealing step (C) there is only 30 ppm of carbon in this standardized depth x, the relative would be Carbon amount f (x) 0.60 or 60%. x in formula (I) means the normalized depth in the flat steel product. In the context of the present invention, “standardized depth in the flat steel product” means that the thickness of the flat steel product is first divided by two, and the value obtained in this way then forms the base value. The respective depths to be considered are then divided by this base value in order to obtain the normalized depth x. With a sheet thickness of 2.5 mm, for example, this means that at a location 0.5 mm below the surface of the sheet, the standardized depth x 40%. The standardized depth x is without units. k is a unitless factor (k factor). According to the invention, k is less than 0.768, preferably less than or equal to 0.5, more preferably -0.5 to 0.7, particularly preferably -0.25 to 0.5.

The present invention also relates to the flat steel product according to the invention, the coating protecting against corrosion containing Zn and unavoidable impurities containing 0.1 to 2.0% by weight of AI and optionally 0.1 to 3% by weight of Mg.

The flat steel product according to the invention can be a hot strip or a cold strip. A cold strip is preferred according to the invention.

The flat steel product can generally have all thicknesses known to the person skilled in the art, for example 0.2 to 1.2 mm, preferably 0.5 to 0.9 mm, in each case including the coating which protects against corrosion. If a steel strip is used according to the invention, it preferably has a width of 500 to 2500 mm, particularly preferably 800 to 2000 mm.

The steel present in the steel flat product according to the invention can generally have any composition. The steel present in the flat steel product according to the invention preferably has a composition which enables a BFI2 value according to SEW094 of> 5 MPa. A flat steel product is particularly preferably used, comprising a steel containing, in addition to Fe and unavoidable impurities (all data in% by weight)

0.00 to 0.3 C,

0.00 to 1.50 Si,

0.01 to 4.00 Mn, 0.00 to 0.10 P,

0.00 to 0.02 S,

0.001 to 2.20 AI,

up to 0.2 Ti + Nb,

up to 1.50 Cr + Mo,

up to 0.25 V,

up to 0.01 N,

0.00 to 0.20 Ni,

up to 0.01 B and

up to 0.01 approx

contains.

The present invention also relates to the component produced by the method according to the invention, at least comprising steps (F) and (G).

According to the invention, the present invention preferably relates to the component according to the invention, it having a SWg value of at most 0.34, particularly preferably at most 0.33, very particularly preferably 0.25 to 0.34, in particular 0.25 to 0.33, in each case after reshaping.

The present invention also relates to the use of a flat steel product according to the invention or a component according to the invention in the automotive sector, in particular for commercial vehicles, in particular trucks, construction machinery and earth moving vehicles, in the industrial sector, for example as rails or telescopic rails, in the construction sector, for example as facade elements, for household appliances, in the energy sector , in shipbuilding.

The details and preferred embodiments mentioned with regard to the method according to the invention apply correspondingly to the flat steel products according to the invention, the component and the use.

characters

Figures 1, 2 and 3 each show three-dimensional coordinate systems, in which the annealing temperature in ° C as the x value, the annealing time in s as the y value and the dew point in ° C as the z value.

The particularly preferred space according to the invention is shown in FIG.

A further space according to the invention is shown in FIG. The entire space, which results from the addition of the space according to FIG. 1 and the space according to FIG. 2, represents the space according to the invention.

FIG. 3 shows a space that is not preferred, according to the invention.

Examples

The following exemplary embodiments serve to explain the invention in more detail. A cold rolled steel strip 0.76 mm thick with the following composition (all percentages by weight) 0.0018 C, 0.004 Si, 0.27 Mn, 0.018 P, 0.007 S, 0.005 AI, 0.026 Cr, 0.014 Cu, 0.002 Mo, 0.003 N, 0.0006 Ti, 0.015 Ni, 0.0002 B, remainder Fe and unavoidable impurities (in our opinion, cleaning does not need to be mentioned) and annealed in a vertical continuous furnace under the process conditions specified in Table 1. The strip is then galvanized on both sides in a hot-dip process (nominal coating weight per side 50 g / m ² ) and treated with an EDT roller with a roller roughness Ra of 2.0 gm. The C content of the annealed cold strip and the absolute decarburization are determined using GDOES. Furthermore, the SWg value was determined by a confocal white light microscope.

Table 1: Examples and comparative examples according to the invention

V comparison test

Industrial applicability

Coated flat steel products which are distinguished by a particularly high-quality surface structure can be obtained by the process according to the invention. These flat steel products can therefore be used advantageously in the automotive sector.

Claims

claims

1. A method for producing a flat steel product with a coating protecting against corrosion, comprising at least the following steps:

(A) providing a flat steel product,

(B) optionally cleaning the flat steel product from step (A),

(C) recrystallizing annealing of the flat steel product from step (A) or (B),

(E) skin pass the flat steel product from step (D) and

(F) Coiling of the coated steel flat product from step (D), characterized in that step (C) is carried out in such a way that the process parameters annealing temperature in ° C, annealing duration in s and dew point in ° C within a three-dimensional coordinate system with the corner points A (870/190/15), B (870/190 / -25), C (830/190/15), D (830/190 / -25), E (870/381/0), K870 / 381 / -25), N (830/381 / -25), F (870/428/0), G (870/490 / 8.5), H (870/490 / -25), K (830/423 / 0), L (830/490 / -8.5), M (830/490 / -25), the annealing temperature by the x value, the annealing time by the y value and the dew point by the z value being represented.

2. The method according to claim 1, characterized in that step (D) is carried out by hot dip coating in a melt bath containing 0.1 to 2.0 wt .-% Al and optionally 0.1 to 3 wt .-% Mg, the rest Zn and inevitable impurities.

3. The method according to claim 1 or 2, characterized in that the flat steel product in addition to Fe and unavoidable impurities (all figures in wt .-%)

0.00 to 0.3 C,

0.00 to 1.50 Si,

0.01 to 4.00 Mn,

0.00 to 0.10 P,

0.00 to 0.02 S,

0.001 to 2.20 AI,

up to 0.2 Ti + Nb,

up to 1.50 Cr + Mo,

up to 0.25 V,

up to 0.01N,

0.00 to 0.20Ni,

up to 0.01B and

contains up to 0.01 Ca.

4. The method according to any one of claims 1 to 3, characterized in that it is carried out continuously.

5. The method according to any one of claims 1 to 4, characterized in that the process parameters annealing temperature in ° C, annealing time in s and dew point in ° C within a three-dimensional coordinate system with the corner points E (870/381/0), F (870 / 428/0), G (870/490 / -8.5), H (870/490 / -25), 1 (870/381 / - 25), J (830/381/0), K (830 / 423/0), L (830/490 / -8.5), M (830/490 / -25), N (830.381, -25).

6. The method according to any one of claims 1 to 5, characterized in that the coating protecting against corrosion is diffusion annealed.

7. A method for producing a component, comprising at least the following steps:

(G) providing a flat steel product with a corrosion protective coating by the method according to any one of claims 1 to 6, and

(H) reshaping the steel flat product from step (G) to obtain the component.

8. The method according to claim 7, characterized in that the shaping in step (G) is carried out by cold shaping.

9. Flat steel product provided with a protective coating against corrosion, produced by a method according to one of claims 1 to 6.

10. Flat steel product provided with a protective coating against corrosion, characterized in that the flat steel product has a carbon distribution according to the following formula (I)

, , (0, 0187 + 0.00957fc) x ³ + (0.4335 - 0.1559fe)% ² + (0, 2563 + 0, lßlk) x + 1 ...

(I)

where f (x), x and k have the following meanings: f (x) relative amount of carbon, based on the original amount of carbon, at a normalized depth x,

x normalized depth in the flat steel product, and

k less than 0.768.

11. Flat steel product according to claim 9 or 10, characterized in that the protective coating against corrosion contains, in addition to Zn and unavoidable impurities, 0.1 to 2.0% by weight of AI and optionally 0.1 to 3% by weight of Mg.

12 component produced by a method according to claim 7 or 8.

13. The component according to claim 12, characterized in that it has a SWq value of at most 0.34.

14. Use of a flat steel product according to one of claims 8 to 11 or a component according to claim 12 or 13 in the automotive sector, in particular for commercial vehicles, in particular trucks, construction machinery and earth moving vehicles, in the industrial sector, for example as housings or telescopic rails, in the construction sector, for example as facade elements, for household appliances, in the energy sector, in shipbuilding.