EP4208576A1 - Steel component produced by hot-shaping a steel flat product, steel flat product and method for producing a steel component - Google Patents

Abstract

The invention provides a steel component which is optimally protected against corrosion and produced by hot-shaping a steel flat product, and also provides a method and a steel flat product which permit the practical production of a steel component of this nature. The steel component comprises a steel substrate which consists of 0.10 – 0.4 % C, 0.05 – 0.5 % Si, 0.5 – 3.0 % Mn, 0.01 – 0.2 % AI, optionally up to 1.0 % Cr, - optionally up to 0.2 % V, < 0.1 % P, < 0.05 % S, < 0.021 % N and optionally in each case one or more elements from the group "B, Ti, Nb, Ni, Cu, Mo, W" where B: 0.0005 – 0.01 %, Ti: 0.001 – 0.1 %, Nb: 0.001 – 0.1 %, Ni: 0.01 – 0.4 %, Cu: 0.01 – 0.8 %, Mo: 0.002 – 1.0 %, W: 0.001 – 1.0 %, and as the remainder Fe and in total < 3 % impurities, and a metal protective coating formed on the steel substrate, which coating is made up of Si, Fe, optionally < 0.6 % Mg and as the remainder AI and < 2 % other constituents and of an alloy layer lying on the steel substrate, which alloy layer contains 35 - 90 % Fe and 5 3 % Si, an Al base layer lying on the alloy layer, which base layer contains 35 - 55 % Fe and < 3 % Si, and an oxide coating lying on the Al base layer and forming the external finish of the metal protective coating, which oxide layer consists of > 80 % oxides, the main portion of the oxides being aluminium oxide and there being present, in the oxide layer, additionally optionally hydroxides and/or magnesium oxide alone or as a mixture, and the remainder of the oxide layer not taken up by the oxides and optionally present hydroxides consisting of Si, AI and/or Mg in metal form (all % values are mass %).

Description

STEEL COMPONENT MANUFACTURED BY HOT FORMING OF A STEEL FLAT PRODUCT, STEEL FLAT PRODUCT AND METHOD OF MANUFACTURING A STEEL COMPONENT

The invention relates to a steel component produced by hot forming of a flat steel product, a method for producing such a component and a flat steel product that is particularly suitable for producing steel components by hot forming.

“Flat steel products” are understood here to mean rolled products whose length and width are significantly greater than their thickness. These include in particular steel strips, steel sheets and blanks obtained from them, such as blanks and the like.

In this text, unless explicitly stated otherwise, information on alloy components is always given in % by mass.

If formulas or conditions are mentioned in the present text in which values are calculated or formed using the contents of certain alloying elements, the relevant contents of alloying elements are used in these formulas or conditions in % by mass, unless otherwise stated.

The composition and thickness of the individual layers of metallic protective coatings produced on steel substrates can be determined using

Glow Discharge Spectroscopy (“GDOES”) according to ISO 11505:2012-12 determine. With the GDOES, the weight percentages of the individual elements are measured across the layer thickness. For this purpose, samples are cut and cleaned with n-heptane. The samples prepared in this way are placed in a glow discharge spectroscope and the layer thickness is measured with a resolution of 10 nm (see htps://de.wikipedia.org/wiki/Glimentladungsspektroskopie - Finding date October 1, 2019).

The steels from which the steel substrates of steel flat products are made, which are processed according to the state of the art and the invention explained here, include in particular the so-called "MnB steels", which are standardized in EN 10083-3. A typical example for such a steel is the steel known under the designation 22MnB5, which can be found in the steel code 2004 under the material number 1.5528.

Typically, fully killed 22MnB5 steel available on the market contains 0.10-0.250% C, 1.0-1.4% Mn, 0.35-0.4% Si in addition to iron and unavoidable impurities (in % by weight). , up to 0.03% P, up to 0.01% S, up to 0.040% Al, up to 0.15% Ti, up to 0.1% Nb, in total up to 0.5% Cr + Mo , and up to 0.005% B.

Steels of the type specified above permit operationally reliable process control in the hot forming of flat steel products made from them into a steel component. Due to their composition, they have the special feature that the steel components made from them by hot forming can be given high strength by heat treatment. For this purpose, the component obtained by hot forming can be specifically cooled in the hot forming tool. At the same time, however, flat steel products and the components hot-formed from them, which consist of steels of the type in question here, are sensitive to corrosive attacks due to the high Mn content of their steel substrate. For this reason, such flat steel products are usually combined with metallic elements before hot forming into the respective steel component protective coatings to protect the steel substrate against corrosion.

EP 2 086 755 B1 discloses a method for producing a hot-formed, coated steel component, in which an aluminum or an aluminum alloy containing, in % by mass, 8-11% Si and 2-4% Fe is produced by hot-dip coating. existing protective layer is applied to a steel strip with a thickness of 20 to 33 μm. The steel strip consists of a steel consisting of, in % by mass, between 0.15 - 0.5% C, between 0.5 - 3% Mn, between 0.1 - 0.5% Si, between 0.01 - 1% Cr, less than 0.2% Ti, less than 0.1% Al, less than 0.1% P, less than 0.05% S and between 0.0005 - 0.08% B, balance iron and unavoidable impurities. Blanks are cut from the coated steel strip and are then held at a specified temperature for a specified period of time, the duration and temperature in each case being chosen as a function of the thickness of the blank. For example, with a circuit board that is 0.7 mm to 1.5 mm thick, the temperatures and annealing times are in a temperature-annealing time coordinate system in a field with the following corner points: Point A - 930 °C, 3 min / point B - 930 °C, 6 min / point C - 880 °C, 13 min / point D - 880 °C, 4 min. With a 1.5 - 3 mm thick blank, on the other hand, temperatures and annealing times should be selected that are in the temperature annealing time coordinate system are arranged in a field determined by the corner points E - 940 °C, 4 min / F - 940 °C, 8 min / G - 900 °C, 6.5 min / H - 900 °C, 13 min. The blanks heated in this way are hot-formed into a steel component, removed from the forming tool and cooled from the hot-forming temperature to 400 °C at a cooling rate of at least 50 °C/s. An Al-based protective layer is present on the component obtained in this way, which is characterized by a four-layer structure, namely an alloy layer which lies on the steel substrate of the component and, in the exemplary embodiment reported in EP 2 086 755 B1, in % by mass, 90% Fe, 7% Al and 3% Si consists of an intermediate layer which lies on the alloy layer and in the embodiment reported in EP 2 086 755 B1 consists of, in mass %, 43% Fe, 57% Al and 1% Si, an intermetallic layer which is on the intermediate layer rests and in the embodiment reported in EP 2 086 755 B1 consists of, in mass %, 65% Fe, 31% Al and 4% Si, as well as a surface layer, which forms the outer end of the metallic protective layer and, in mass -%, 45% Fe, 54% Al and 1% Si.

From CN 102 851 629 B another method for hot dip coating of steel sheets intended for hot press forming is known. In this known method, the metal sheet is hot-dip coated with an aluminum-based coating that protects against corrosion before it is formed. The coating contains 0.1-0.3% by mass of rare earths, 1.3-3.8% by mass of Si and the remainder aluminum. Before hot-dip coating, the respective steel sheet is first exposed to an oxidizing atmosphere formed from a combustible gas, such as coal gas, and air with a mixing coefficient of 0.8 - 1.2 at temperatures of 600 - 700 °C and a dew point of -10 °C annealed up to 30 °C. The steel strip then goes through a second annealing step at an annealing temperature of 800 - 850 °C in a reducing atmosphere with an H ₂ content of 20 - 50% by volume, the remainder N and a dew point of -20 °C to -60 °C.

In addition, a flat steel product is known from EP 2 993 248 A1, which is intended for hot forming into a steel component. The steel substrate of the steel flat product consists of a steel which has 0.1-3% by mass Mn and up to 0.01% by mass B. A protective coating based on Al, which is typically an AlSi coating, is applied to the steel substrate and contains 3-15% by mass of Si in addition to Al other alloy components, such as up to 5% by mass Fe, be included. As an additional alloy component, the Al protective coating contains a total of 0.005 - 0.7% by mass of at least one alkaline earth metal or transition metal. This additional alloy component minimizes the absorption of hydrogen during the heating required for hot forming, with the addition of Mg or Ca having turned out to be particularly suitable for these purposes.

EP 2 982 772 A1 also explains examples of the conventional procedure for hot press forming.

In addition to optimizing protection against corrosion, the aim of the developments described above and known from the prior art is to improve the economic efficiency with which the hot forming process can be carried out without sacrificing stability and resistance to disturbances.

Proceeding from the prior art explained above, the task therefore arose of specifying a steel component which is optimally protected against corrosion by a metallic protective coating based on Al and which is produced by hot forming a flat steel product and which can be produced in a particularly practical manner.

According to the invention, a component that achieves this object has at least the features specified in claim 1 .

In addition, a method should be specified with which steel components that are optimally protected against corrosive attacks can be produced by hot forming in shortened process times.

According to the invention, a method that achieves this object has at least the features specified in claim 9 . It goes without saying that a person skilled in the art, when carrying out the method according to the invention and its variants and expansion options explained here, adds those work steps not explicitly mentioned here, which he knows from his practical experience that they are regularly used when carrying out such methods .

Finally, a flat steel product should also be specified that is optimally suited for producing a steel component by hot forming.

According to the invention, a steel component that achieves this object has at least the features specified in claim 16 .

Advantageous refinements of the invention are specified in the dependent claims and, like the general inventive concept, are explained in detail below.

According to the invention, a steel component produced by hot forming a flat steel product comprises

- a steel substrate consisting of, in % by mass,

0.10 - 0.4% C, 0.05 - 0.5% Si, 0.5 - 3.0% Mn, 0.01 - 0.2% Al, optionally up to 1.0% Cr, in particular 0.005-1.0% Cr, optionally up to 0.2% V, in particular 0.001-0.2% V, <0.1% P, <0.05% S, <0.021% N and optionally one element each or more elements from the group "B, Ti, Nb, Ni, Cu, Mo, W" and the remainder consists of iron and a total of up to 3% unavoidable impurities, whereby for the optionally present contents of "B, Ti , Nb, Ni, Cu, Mo, W" applies:

B: 0.0005 - 0.01%, Ti: 0.001 - 0.1%, Nb: 0.001 - 0.1%, Ni: 0.01 - 0.4%, Cu: 0.01 - 0.8% , Mo: 0.002 - 1.0%, W: 0.001 - 1.0%, and - a metallic protective coating formed on the steel substrate based on aluminum with contents of Si, Fe and optionally up to 0.6% by mass Mg as well as other components whose total contents are limited to a maximum of 3% by mass, the metallic protective coating consists of three distinct layers viz

- an alloy layer lying on the steel substrate, which contains 35 - 90% by mass Fe and at most 3% by mass Si,

- an Al base layer lying on the alloy layer and containing 35-55% by mass of Fe and less than 3% by mass of Si, and

- an oxide layer lying on the Al base layer and forming the outer end of the metallic protective coating, which consists of more than 80% by mass of oxides, the main part of the oxides being aluminum oxide and in the oxide layer additionally optionally hydroxides and/or magnesium oxide alone or are present as a mixture and the remainder of the oxide layer not occupied by the oxides and optionally present hydroxides consists of silicon, aluminum and magnesium.

A method according to the invention for the production of a hot-formed steel component, which is provided with a metallic protective coating consisting of contents of Si, Al, Fe and optionally up to 0.6% by mass Mg and other components, the contents of which total up to a maximum of 3 mass -% are limited, includes the following work steps: a) Provision of a cold-rolled, 0.6 - 3 mm thick steel flat product, which consists of, in % by mass,

C: 0.10 - 0.4%, Si: 0.05 - 0.5%, Mn; 0.5 - 3.0% Al: 0.01-0.2% optionally Cr: up to 1.0%, in particular 0.005-1.0% optionally V: up to 0.2%, in particular 0.001-0.2%

P: <0.1%

S: <0.05%

N: <0.021% and optionally one or more elements from the group "B, Ti, Nb, Ni, Cu, Mo, W" with the proviso that the optionally present B content is 0.0005 - 0.01% , the optionally present Ti content 0.001 -0.1%, the optionally present Nb content 0.001 - 0.1%, the optionally present Ni content 0.01 - 0.4%, the optionally present Cu content 0, 01-0.8%, the optionally present Mo content is 0.002-1.0% and the optionally present W content is 0.001-1.0%, and the remainder consists of iron and a total of at most up to 3% unavoidable impurities , b) heating the steel flat product to a melt bath inlet temperature BET of 600-740 °C, with the heating

- a first annealing step, in which the steel flat product is exposed to an annealing atmosphere consisting of at least 90% by volume of N ₂ and the remainder of H ₂ and technically unavoidable impurities and having a dew point of -15 °C to +60 °C one

heating rate of 20 - 90 K/s to an annealing temperature GT1 of 550 - 750 °C and held at the annealing temperature GT1 for a period of 10 s to 360 s,

- a second annealing step, in which the flat steel product, heated to annealing temperature GT1, is exposed to an annealing atmosphere consisting of at least 90% by volume of N ₂ and the remainder of H ₂ and technically unavoidable impurities and a dew point of -50 °C to +5 °C, with a heating rate of 0.5 - 30 K/s, in particular 0.5 - 10 K/s, heated to an annealing temperature GT2 which is higher than the annealing temperature GT1 and is 700 - 850 °C and is maintained at the annealing temperature GT2 for a period of 10 s to 360 s, and

- includes a cooling step in which the steel flat product is cooled from the annealing temperature GT2 at a cooling rate of 0.5 K/s to 40 K/s to the melt bath entry temperature BET, c) passing through the steel flat product cooled to the melt bath entry temperature BET a molten bath heated to 680 - 720 °C, which consists of, in % by mass,

Si: 0.05 - 3%

Fe: 0.1 - 6%, optionally Mg: <0.7% and the remainder consists of Al and a total of at most 3% unavoidable impurities, d) setting a thickness of 10 - 30 μm of the metallic applied to the steel flat product in the melt bath protective coating by stripping excess melt from the flat steel product emerging from the melt bath using a stripping gas, e) heating a blank cut from the flat steel product in a furnace for a furnace residence time OVZ of 60 s to 180 s to a hot forming temperature WUT of 820 - 1000 °C , f) hot forming of the blank heated to the hot forming temperature to form the steel component; g) cooling the steel component obtained at a cooling rate of

10K/s to 100K/s. The steel substrate of a steel component according to the invention and an im

Step a) of a method according to the invention provided

Steel flat product consists of a composition typical of MnB steels.

A metallic protective coating, which consists of more than 92% by mass of aluminum and has contents of Si, Fe and optionally Mg, is produced on the steel substrate composed in this way by means of hot-dip coating carried out in a conventional manner. For this purpose, in the method according to the invention, the flat steel product is passed through a molten bath whose composition corresponds to the metallic protective coating present on the flat steel product when it exits the molten bath. Only in step e) of the method according to the invention, i.e. during heating to the respective hot forming temperature and subsequent holding for the respective heating period at the hot forming temperature, does the previously conventionally applied Al-based coating become the three-layer characteristic of a steel component according to the invention Construction of the protective coating of the steel component.

Silicon (“Si”) is present in the protective coating applied to the flat steel product in step c) according to the invention in order to adjust the iron diffusion into the aluminum coating. However, the Si content is limited to at most 3% by mass, in particular less than 2% by mass or less than 1.5% by mass. In this way, it is achieved that even in the protective layer applied in step c), an iron-rich alloy layer is formed that is adjacent to the steel substrate of the steel flat product and can extend on average over 1-100% of the total thickness of the protective layer, whereby it typically has a thickness , which on average corresponds to at least 10%, in particular more than 35%, of the total thickness of the protective coating obtained on the flat steel product according to step c). Alloy layers with a thickness of at least 10% of the total thickness of the coating can be achieved reliably with Si contents of less than 2% by mass, whereas alloy layers with a thickness of at least 35% on average Total thickness of the coating can be guaranteed with Si contents of the melt bath and the coating of less than 1.5% by mass. The formation of an alloy layer, the thickness of which on average regularly corresponds to more than 35% of the total thickness of the protective coating present on the steel flat product after step c) and before step e) can be particularly reliably achieved with Si contents of the melt bath and the associated ensure the coating produced on the steel flat product is 0.05% by mass. The high iron content in the protective coating that occurs due to the low Si content is the prerequisite for the heating to the hot forming temperature WUT being able to be carried out in furnace residence times that are significantly shorter than in the prior art.

In order to support the formation of the alloy layer with high iron content desired according to the invention, iron ("Fe") in contents of 0.1% to 6% by mass, in particular of at least 2 .5% by mass. Fe contents above 6% by mass would increase the melting point of the molten bath to such an extent that a coating composed according to the invention could no longer be applied economically by conventional hot-dip coating.

Magnesium ("Mg") can optionally be contained in the melt bath in amounts of up to 0.7% by mass in order to significantly influence the formation of the oxide layer and thus minimize the diffusion of hydrogen into the steel substrate. However, Mg and Fe atoms can replace each other in the metallic lattice. Since there could be competition between Mg and Fe due to their similar atomic radii, at most small additions of Mg of at most 0.7% by mass are permitted according to the invention. Higher Mg contents would run counter to the desired rapid heating during heating to the hot forming temperature WUT in work step e) of the method according to the invention due to the associated changed diffusion processes. Therefore, the Mg content of the melt pool and thus along with the protective coating produced on a steel flat product provided according to the invention is preferably limited to less than 0.5% by mass, the advantages of the presence of Mg without negative effects on the duration of the heating in step e) at Mg contents of 0.1 - 0.4% by mass can be used particularly safely.

Before entering the melt bath, the steel flat product to be hot-dip coated is heated in step b) of the process according to the invention in two stages to a melt bath entry temperature BET of 600-740° C., in particular at most 730° C. or at most 720° C., with bath entry temperatures increasing BET of at least 620 °C, in particular at least 670 °C, have proven particularly useful. In the first stage of heating, the respective flat steel product is heated in an annealing atmosphere consisting of at least 90% by volume N ₂ and the remainder H ₂ as well as technically unavoidable impurities and having a dew point of -15 °C to +60 °C at a heating rate of 20 - 90 K/s to an annealing temperature GT1 of 550 - 750 °C, in particular 600 - 700 °C, and held at the annealing temperature GT1 for a period of 10 s to 360 s in order to adjust the structure.

This first annealing step is followed by a second annealing step, in which the flat steel product heated to the annealing temperature GT1 is exposed to an annealing atmosphere that also consists of at least 90% by volume of N ₂ and the remainder consists of H ₂ and technically unavoidable impurities, but has a dew point from -50 °C to +5 °C, in particular -40 °C to -15 °C, with a heating rate of 0.5 - 30 K/s, in particular 0.5 - 10 K/s to an annealing temperature GT2 heated, which is higher than the annealing temperature GT1 and 700 - 850 ° C, in particular 710 - 790 ° C, and is held at the annealing temperature GT2 for a period of 10 s to 360 s in order to adjust the structure. Following the second annealing step, the flat steel product is cooled in a cooling step from the annealing temperature GT2 to the respective melt bath entry temperature BET. The cooling rate is 0.5 K/s to 40 K/s to bring the steel strip to the necessary strip immersion temperature.

The steel flat product thus heat-treated and heated to the respective bath entry temperature BET is passed in a conventional manner through a melt bath, the temperature of which is 680 - 720 °C.

The thickness of the Al-based protective coating on the flat steel product emerging from the molten bath is adjusted in an equally conventional manner by stripping off excess coating material to a thickness of 10-30 μm, in particular 12-25 μm, on each side of the flat steel product. A conventional wiping nozzle is used for wiping, from which, according to the invention, .e.g. compressed air, which typically has an O ₂ content of 15-23% by volume and an N ₂ content of 76-85% by volume, is used as the wiping medium the rest not taken up by O ₂ and N ₂ consists of carbon dioxide, noble gases, water and other components usually present in the ambient air, or nitrogen gas is discharged, the N ₂ content of which is more than 90% by volume with a dew point of less than + is 15 °C.

A flat steel product according to the invention for producing a steel component by hot forming accordingly comprises a steel substrate which consists of, in % by mass, 0.10-0.4% C, 0.05-0.5% Si, 0.5-3.0% Mn, 0.01-0.2% Al, optionally up to 1.0% Cr, in particular 0.005-1.0% Cr, optionally up to 0.2% V, in particular 0.001-0.2% V, <0 1% P, <0.05% S, <0.021% N and optionally one or more elements from the group “B, Ti, Nb, Ni, Cu, Mo, W” and the remainder of iron and in There is a total of up to 3% unavoidable impurities, whereby the following applies to the optionally present contents of "B, Ti, Nb, Ni, Cu, Mo, W": B: 0.0005 - 0.01%, Ti: 0.001 - 0.1%, Nb: 0.001 - 0.1%, Ni: 0.01 - 0.4%, Cu: 0.01 - 0.8%, Mo: 0.002 - 1.0 %, W: 0.001 - 1.0%, and an Al-based protective layer overlying the steel substrate. According to the invention, the Al-based protective layer comprises three layers, namely an alloy layer lying on the steel substrate, which consists of 35-60% by mass Fe, less than 3% by mass Si, optionally up to 0.7% by mass Mg, in particular up to 0.6% by mass Mg, and the remainder consists of Al and unavoidable impurities, the total content of which can be 3% by mass, an Al base layer lying on the alloy layer and connected to it, which consists of less than 35 mass % Fe, less than 3% by mass Si, optionally less than 0.7% by mass Mg and the balance consists of Al and unavoidable impurities, the total contents of which can be at most 3% by mass, and one on the Al base layer lying and connected to this, the outer end of the metallic protective layer forming oxide layer in which optionally up to less than 0.7% by mass of Mg and up to 3% by mass of other components are present and the rest consists of Al, the Al the oxide layer s owie, if present, the Mg of the oxide layer in each case in oxidic or hydroxide form.

A flat steel product of this type according to the invention is present when the method according to the invention is carried out as an intermediate product after the hot-dip coating carried out in the manner according to the invention, i.e. after step d) and before step e).

From the steel flat product thus provided with the protective coating by hot-dip coating, a blank is cut off in a conventional manner, the dimensions of which are selected such that the respective steel component can be hot-formed in one piece by the subsequent hot-forming process.

The blank is then heated in a furnace for a furnace dwell time OVZ of 60 s to 180 s to a hot forming temperature WUT of 820 - 1000 °C.

The blank is preferably heated to the above-mentioned temperature at a heating rate of 1 to 200° C./s, in particular at most 30° C./s, with Heating rates of 3 - 20 °C/s have proven particularly effective in practice. The heating can take place at a uniform heating rate up to the respective warm transformation temperature WUT. However, it can also be expedient to carry out the heating in at least two successive stages, with the heating being carried out in the first stage at a mean heating rate of 3-50° C./s, in particular 6-20° C./s or 8-16° C/s, and in the second stage the heating is carried out at a heating rate of 1-10° C./s, in particular 2-5° C./s. In this way, a homogeneous iron enrichment is achieved with optimal economy.

When heated to the hot forming temperature WUT, the diffusion of iron into the aluminium-based protective coating of the blank takes place just as quickly as the transformation of the microstructure of the steel substrate into the austenitic state that accompanies the heating. Within a short period of heating, for example, a protective coating that is fully alloyed with iron forms on the circuit board, with at least 35% by mass of Fe present in the alloy layer and in the Al base layer.

The incorporation of Fe into the Al base layer is of crucial importance here, since only those aluminium-based coatings are considered to be workable in the large-scale process of hot forming, in which pure aluminum at the limit of the Al base layer below the oxide layer is at best in contents of less than <5% by mass. Higher levels of pure aluminum would bring with it the risk that when inserting the respective warmümzuformenden, heated to the warm-forming temperature board in the hot-forming tool, larger amounts of AI would still be present in molten form on the surface of the board, which would lead to undesirable effects in the hot-forming tool Caking and adhesions of coating material that interfere with the forming process could occur.

Since the process of diffusing the iron into the protective coating is synchronous with the

Austenitization of the steel substrate takes place when the invention

No longer modifies the furnace dwell time through the diffusion process of the iron determined in the cover. The reduction in the Si content carried out according to the invention thus leads to a significant reduction in the time spent in the furnace compared to conventional production methods, which a blank coated according to the invention requires for heating to the hot forming temperature and the associated formation of an optimally effective metallic protective coating based on Al allows not only to shorten the process times when using conventional furnaces (roller hearth furnaces), but also to use heating technologies such as induction, conduction or plate heating, with which the processed blank can be heated to the respective hot forming temperature within a further reduced time without that there is a melting of the aluminum present in the protective coating. by limiting the furnace dwell time OVZ to a maximum of 120 s, an Al-based protective coating can be produced on the steel component produced according to the invention, in its alloy layer 35-60% by mass Fe and optionally up to 0.6% by mass Mg while at the same time being far below 3 mass% lying Si contents are present.

The Si content present in the protective cover is evenly distributed over the Al base layer and the alloy layer. The Si content of the alloy layer is typically 0.5% by mass, with Si contents of at least 0.05% by mass being found regularly in the alloy layer in practice, Si contents of the Al base layer of 0.5 to 1.5% by mass can be expected.

Surprisingly, it has been found that longer furnace dwell times OVZ have no effect on the composition of the Al-based layer of the protective coating produced according to the invention, which is present between the oxide layer and the alloy layer on the steel substrate. For the invention Oven residence times OVZ of less than 180 s, in particular at most 120 s or at most 110 s, are therefore particularly suitable for purposes.

However, if the alloy layer has a Si content of 0.7-3% by mass and an optionally present Mg content of the alloy layer of up to 0.2% by mass Mg, in particular at least 0.05% by mass Mg, the If the Fe content of the alloy layer is increased to 55-90% by mass, this can be achieved by an oven residence time OVZ lasting more than 110 s, in particular more than 120 s, with the alloying of the iron in the alloy layer also taking place within compared to the State of the art of shortened oven residence times, typically less than 180 s.

In step f), the blank that has been heated through to the hot-forming temperature WUT is hot-formed in a conventional manner in an equally conventional hot-forming tool to form the steel component.

The steel component obtained is then, as is also customary in the prior art, cooled at a cooling rate of 10-360 K/s in order to obtain the desired mechanical properties of the component.

In accordance with the above explanations, the method according to the invention is particularly suitable for producing a steel component according to the invention.

The invention is explained in more detail below using exemplary embodiments. Show it:

1 shows the result of a GDOES depth measurement of an Al-based protective coating alloyed according to the invention on a steel component produced in a manner according to the invention, the furnace dwell time over which the blank, from which the steel structure was hot-formed was heated to a hot-forming temperature WUT of 920 °C for 90 s;

Fig. 2 shows the result of a GDOES depth measurement of the Al-based protective coating alloyed according to the invention of a steel component produced in the manner according to the invention, the furnace dwell time over which the blank from which the steel component was hot-formed heated to the hot-forming temperature WUT of 920 °C has been 90 s;

3 shows an optical micrograph of a cross section of a cross section of an AF-based coating applied by hot dip coating in the manner according to the invention, before heating to the hot forming temperature WUT, magnified 1000 times, according to DIN EN ISO 3887.

In FIGS. 1 and 2, the contents of Fe, Zn, AS, C and O are shown based on 100% by mass, whereas the contents of Mg, Mn and Si are shown based on 10% by mass.

1 shows that with a metallic protective coating with 2% silicon, 0.5% magnesium, 2.8% Fe and the remainder aluminum and up to 3% unavoidable impurities, the alloy layer and the Al-based layer change when heated to the hot forming temperature WUT of 920 °C over a furnace dwell time OVZ of up to 110 s, a clearly definable alloy layer is initially developed. The transition between the alloy layer of the metallic protective layer and the steel substrate of the steel component is around 20 μm, measured starting from the free surface of the protective coating. The alloy layer sweeping on the steel substrate extends over a thickness of approx. 6 μm and a depth of 14 - 20 μm, measured from the free surface of the protective cover. On top of the alloy layer is an Al-based layer that extends to a depth of about 0.5 μm to 14 μm measured from the free surface of the protective coating and is accordingly about 13.5 μm thick. The top 0.5 μm of the thickness of the protective coating is occupied by the oxide layer overlying the Al-based layer. the

The oxide layer consists of aluminum oxides and hydroxides, magnesium oxides and hydroxides and mixtures of these oxides and hydroxides.

FIG. 2 shows the state that occurs after an oven dwell time OVZ of more than 110 s but less than 180 s. Both in the state shown in FIG. 1 and in the state shown in FIG. 2, the coating layers are fully alloyed with iron and are accordingly to be regarded as finished.

To test the invention, five cold-rolled steel strips, each 1.5 mm thick, were provided, the steel substrates of which consisted of steels A-E alloyed according to Table 1.

One of the metallic protective coatings Z1-Z4 was applied to the steel strips thus provided by hot-dip coating, the composition of which is given in Table 2 after hot-dip coating but before heating for hot forming. The procedure here was as follows: In a first annealing step, a cold strip is heated to 670° C. for 20 seconds at a heating rate of 60 K/s. The atmosphere there consists of 95% nitrogen, up to 5% hydrogen, dew point +40°C and unavoidable impurities. The strip is brought directly into the second annealing zone, where it is heated at 20 K/s to 770 °C and held at this temperature for 50 seconds. The atmosphere only changes in terms of the dew point, which is lowered to -40 °C. The strip is then cooled to 700 °C at a cooling rate of 10 K/s. With a strip temperature of 700 °C, the strip is immersed in the liquid melt. Melting bath temperature also corresponds to 700 °C. the The melt is composed as follows: 1.5% by mass of silicon, 2.8% by mass of iron and 0.5% by mass of magnesium, the remainder being aluminum and, in this example, up to 1% of unavoidable impurities.

Ten samples V1 - V10 of the steel strips A - E each hot-dip coated with one of the protective coatings Z1 - Z4 with a coating weight AG are heated in a furnace usually used for this purpose in the prior art for a furnace residence time OVZ to a hot forming temperature WUT, then in a conventional one Formed into a steel component and finally cooled to room temperature at a cooling rate of 20 K/s.

The steel from which the steel substrate of the respective sample V1 - V10 consisted, the respective coating applied to the steel substrate, the coating weight AG, the respective hot forming temperature WUT and the respective furnace dwell time OVZ are given in Table 3. The proportion %DL of the thickness of the alloy layer in the total thickness of the coating and the layer structure of the coating were determined on the steel components thus obtained by light microscopic examination in the manner described above. The results of this study are summarized in Table 4.

Finally, the compositions of the Al base layer and the alloy layer of the protective coatings present on the steel components produced from samples V1-V10 were determined by means of GDOES analysis in the manner also described above. The results of these investigations are summarized in Table 5. The maximum and minimum existing contents are given for Al, Si and Fe, as far as determined or ascertainable.

Fig. 3 shows the typical structure of a protective layer present on a steel flat product according to the invention, which is an intermediate product after the hot-dip coating (step d)) carried out in the manner according to the invention and is particularly suitable for the hot forming to a steel component, which takes place in the manner according to the invention.

To produce the steel flat product sample, the protective layer structure of which is shown in

3 shows a conventionally produced, 1.5 mm thick cold-rolled steel strip consisting of steel C at a heating rate of 50 K/s under a nitrogen atmosphere of at least 95% by volume and bis heated to an annealing temperature GT1 of 625° C. in an annealing atmosphere consisting of 5 vol. The dew point of the annealing atmosphere under which this first annealing step took place was +30°C.

Directly after the first annealing step, the flat steel product heated to the annealing temperature GT1 was heated at a heating rate of 9 K/s to an annealing temperature GT2, which was 780°C. The steel strip heated in this way was held at the annealing temperature GT2 for an annealing period of 180 s. This second annealing step took place under an annealing atmosphere which has only been changed in relation to the atmosphere of the first annealing step with regard to its dew point, which is now -35° C. for the second annealing step.

At the end of this annealing period, the cold-rolled steel strip was cooled at a cooling rate of 25 K/s to a melt bath inlet temperature BET of 680°C.

The cold-rolled steel strip cooled in this way was passed through a molten bath heated to 680° C., which consists of 0.2% by mass Si and 0.3% by mass Mg, 1.5% by mass Fe and the balance Al and the total at most 3% by mass of unavoidable impurities. At the end of the production of the intermediate product, the thickness of the metallic protective coating applied to the flat steel product in the molten bath was adjusted to 20 μm by conventional stripping using a stripping gas.

3 also shows how micrographs can be used to determine the alloy layer thickness. The layer thicknesses are determined by light microscopy. To do this, cross-sections are polished and etched with 3% nital solution. Under the light microscope, the alloy layer on the steel substrate appears clearly darker when viewed in bright field and magnified 1000 times than the underlying Al base layer, which in turn can be distinguished just as clearly from the oxide layer forming the outer end of the protective coating, which can be seen as a dark, thin layer can.

The invention thus provides steel components which are optimally protected against corrosion and are produced by hot forming of a flat steel product, as well as a method and a flat steel product which enable the practical production of such a steel component. A steel component according to the invention includes

- a steel substrate consisting of 0.10 - 0.4% by mass C, 0.05 - 0.5% by mass Si, 0.5 - 3.0% by mass Mn, 0.01 - 0.2% by mass -% Al, optionally up to 1.0% by mass Cr, in particular 0.005-1.0% by mass Cr, optionally up to 0.2% by mass V, in particular 0.001-0.2% by mass V, <0 1% by mass P, <0.05% by mass S, <0.021% by mass N and optionally one or more elements from the group “B, Ti, Nb, Ni, Cu, Mo, W” with the proviso that the content of B is 0.0005 - 0.01% by mass, the content of Ti is 0.001 - 0.1% by mass, the content of Nb is 0.001 - 0.1% by mass, the content of Ni is 0.01 - 0.4% by mass, the Cu content is 0.01 - 0.8% by mass, the Mo content is 0.002 - 1.0% by mass, the W content is 0.001 - 1.0% by mass, and the remainder consists of Fe and a total of <3% by mass of impurities, as well as - A metallic protective coating formed on the steel substrate, which is composed of Si, Fe, optionally <0.6% by mass Mg and the remainder of Al and ä 2% by mass of other components and which consists of an alloy layer lying on the steel substrate 35 - 90 wt% Fe and <3 wt% Si, an Al base layer overlying the alloy layer containing 35 - 55 wt% Fe and <3 wt% Si, and one overlying the Al base layer , the oxide layer forming the outer end of the metallic protective coating consists of > 80% by mass of oxides, the main proportion of the oxides being aluminum oxide and the oxide layer additionally optionally containing hydroxides and/or magnesium oxide alone or as a mixture and with the not The remainder of the oxide layer occupied by the oxides and optionally present hydroxides consists of Si, Al and/or Mg in metallic form (all mass percentages given in mass-mass%).

Table 3

Table 4

Table 5

Claims

P AT E N T C H A N G L I G E S S Steel component manufactured by hot forming a flat steel product,

- with a steel substrate consisting of, in % by mass, 0.10 - 0.4% C, 0.05 - 0.5% Si, 0.5 - 3.0% Mn, 0.01 - 0.2 % Al, optionally up to 1.0% Cr, -optionally up to 0.2% V, <0.1% P, <0.05% S, <0.021% N and each optionally consisting of one element or more elements of the group "B, Ti, Nb, Ni, Cu, Mo, W" and the remainder consists of iron and a maximum total of up to 3% unavoidable impurities, whereby for the optionally present contents of "B, Ti, Nb, Ni , Cu, Mo, W" applies: B: 0.0005 - 0.01%, Ti: 0.001 - 0.1%, Nb: 0.001 - 0.1%, Ni: 0.01 - 0.4%, Cu : 0.01 - 0.8%, Mo: 0.002 - 1.0%, W: 0.001 - 1.0%, and

- formed on the steel substrate with a metallic protective coating based on aluminum with contents of Si, Fe and optionally up to 0.6% by mass Mg and other components whose total contents are limited to a maximum of 2% by mass, with the metallic Protective coating consists of three distinct layers, viz

- an alloy layer lying on the steel substrate, which contains 35 - 90% by mass Fe and at most 3% by mass Si,

- an Al base layer lying on the alloy layer and containing 35-55% by mass of Fe and less than 3% by mass of Si, and - an oxide layer lying on the Al base layer and forming the outer finish of the metallic protective coating, which consists of more than 80% by mass of oxides, the main proportion of the oxides being aluminum oxide and in the oxide layer additionally optionally hydroxides and/or magnesium oxide alone or are present as a mixture and wherein the remainder of the oxide layer not occupied by the oxides and optionally present hydroxides consists of silicon, aluminum and/or magnesium in metallic form. Steel component according to claim 1, characterized in that in the alloy layer 35 - 60% by mass Fe , and optionally up to 0.6% by mass Mg are present. Steel component according to Claim 2, characterized in that the Si content of the alloy layer is less than 3% by mass. Steel component according to claim 1, characterized in that the Fe content of the alloy layer is 55-90% by mass, the Si content of the alloy layer is 0.7-3% by mass and the optionally present Mg content of the alloy layer is up to 0.3 Mass% is. Steel component according to one of the preceding claims, characterized in that the Si content of the alloy layer is at least twice as high as the Si content in the Al base layer. Steel component according to one of the preceding claims, characterized in that the Si content of the Al base layer is at most 3% by mass. Steel component according to one of the preceding claims, characterized in that the Mg content of the metallic protective coating is at least 0.1% by mass, that the Mg content is distributed over the upper third of the thickness of the metallic protective coating adjacent to the free outside of the oxide layer and that more than 50% of the Mg content is bound in the oxide layer. Steel component according to one of the preceding claims, characterized in that the thickness of the metallic protective coating is 10 - 30 µm. Process for the production of a hot-formed steel component which is provided with a metallic protective coating consisting of Si, Al, Fe and optionally up to 0.6% by mass of Mg and other components whose total contents are limited to a maximum of 2% by mass are limited, comprising the following work steps: a) Provision of a cold-rolled, 0.6 - 3 mm thick steel flat product, which consists of, in % by mass,

C: 0.10 - 0.4%,

Si: 0.05 - 0.5%,

Mn: 0.5 - 3.0%

AI: 0.01 - 0.2% optional Cr: up to 1.0% optional V: up to 0.2%

P: <0.1%

S: <0.05%

N: <0.021% and optionally one or more elements from the group "B, Ti, Nb, Ni, Cu, Mo, W" with the proviso that the optionally present B content is 0.0005-0.01%, the optionally present Ti content 0.001 -0.1%, the optionally present Nb content 0.001 - 0.1%, the optionally present Ni content 0.01 - 0.4%, the optionally present Cu content 0.01 - 0.8 %, the optionally present Mo content is 0.002-1.0% and the optionally present W content is 0.001-1.0%, and the remainder consists of iron and a total of at most up to 3% unavoidable impurities, b) heating the Steel flat product to a melt bath entry temperature BET of 600 - 740 °C, with the heating

- a first annealing step, in which the steel flat product is exposed to an annealing atmosphere consisting of at least 90% by volume of Na and the remainder of H ₂ and technically unavoidable impurities and having a dew point of -15 °C to +60 °C, with a heating rate of 20 - 90 K/s to an annealing temperature GT1 of 550 - 750 °C and held at the annealing temperature GT1 for a period of 10 s to 360 s,

- a second annealing step, in which the flat steel product heated to annealing temperature GT1 is exposed to an annealing atmosphere consisting of at least 90% by volume of N ₂ and the remainder of H ₂ and technically unavoidable impurities and a dew point of -50 °C to +5 °C at a heating rate of 0.5 - 30 K/s to an annealing temperature GT2 which is higher than the annealing temperature GT1 and is 700 - 850 °C and for a period of 10 s to 360 s at the annealing temperature GT2 is held and

- includes a cooling step in which the steel flat product is cooled from the annealing temperature GT2 at a cooling rate of 0.5 K/s to 40 K/s to the melt bath entry temperature BET, c) passing the steel flat product cooled to the melt bath entry temperature BET through a melt bath heated to 680 - 720 °C, which consists of, in % by mass,

Si: 0.05 - 3%

Fe: 0.1 - 6%, optionally Mg: <0.7% and the remainder consists of Al and a total of at most 3% unavoidable impurities, d) setting a thickness of 10 - 30 μm of the metallic applied to the steel flat product in the melt bath protective coating by stripping excess melt from the flat steel product emerging from the melt bath using a stripping gas, e) heating a blank cut from the flat steel product in a furnace for a furnace residence time OVZ of 60 s to 180 s to a hot forming temperature WUT of 820 - 1000 °C f) hot forming of the blank heated to the hot forming temperature, g) cooling of the resulting steel component at a cooling rate of 10 K/s to 100 K/s.

. Process according to Claim 9, characterized in that the furnace residence time OVZ is at most 120 s. . Process according to Claim 9, characterized in that the oven residence time OVZ is more than 120 s. . Method according to one of Claims 9 - 11, characterized in that the oven residence time OVZ is at least 90 s. : Method according to one of Claims 9-12, characterized in that after step d) and before step e) there is a metallic protective coating on the steel substrate which consists of an alloy layer lying on the steel substrate and consisting of 35 - 60 mass % Fe, less than 3% by mass Si, optionally up to 0.6% by mass Mg and the remainder consists of Al and unavoidable impurities, the total content of which can be 3% by mass, from an Al base layer consisting of less than 35% by mass Fe, less than 3% by mass Si, optionally less than 0.7% by mass Mg and the remainder consists of Al and unavoidable impurities, the total content of which does not exceed 3% by mass, and one oxide layer lying on the Al base layer forming the outer finish of the metallic protective coating, the Al content of which is 90-99% by mass, with the oxide layer optionally containing less than 0.7% by mass of Mg and up to 3% by mass of others components are present. Method according to one of Claims 9 - 13, characterized in that the annealing temperature GT1 in step b) is GT1600 - 700 °C and the annealing temperature GT2710 - 790 °C. Steel component according to any one of claims 1 to 8 produced by a method according to any one of claims 9-14. Steel sheet for producing a steel component by hot forming, the steel sheet comprising a steel substrate consisting of, in % by mass, 0.10 - 0.4% C, 0.05 - 0.5% Si, 0.5 - 3.0% Mn, 0.01-0.2% Al, optionally up to 1.0% Cr, optionally up to 0.2% V, <0.1% P, <0.05% S, <0.021% N and each optionally consists of one element or more elements from the group "B, Ti, Nb, Ni, Cu, Mo, W" and the remainder consists of iron and a total of up to 3% unavoidable impurities, whereby for the optionally present contents of " B, Ti, Nb, Ni, Cu, Mo, W" applies: B: 0.0005 - 0.01%, Ti: 0.001 - 0.1%, Nb: 0.001 - 0.1%, Ni: 0.01 - 0.4%, Cu: 0.01 - 0.8%, Mo: 0.002 -1.0%, W: 0.001 -1.0%, and an Al-based protective layer overlying the steel substrate, characterized that the protective layer comprises the following three layers:

- an alloy layer lying on the steel substrate and connected to it, which consists of, in mass %, 35 60% Fe, less than 3% Si, optionally up to less than 0.7% Mg and the balance of Al and unavoidable impurities, the total content of which does not exceed 3%, an Al base layer lying on the alloy layer and connected to it, which consists of, in % by mass, less than 35% Fe, less than 3% Si, optionally less than 0.7% Mg and as a remainder from AI and unavoidable impurities, the total content of which does not exceed 3%, and

- An oxide layer lying on the Al base layer and connected to it, which forms the outer finish of the metallic protective layer and consists of, in % by mass, optionally up to less than 0.7% Mg present in oxidic or hydroxide form and the remainder made up of AI in oxidic or hydroxide form and up to 3% by mass of other components.