DE102022122771A1 - Sheet steel for spot-free phosphating - Google Patents

Abstract

The invention relates to a hot-dip coated and tempered steel sheet, a method for its production and a use.

Description

The invention relates to a steel sheet which is hot-dip refined and tempered, the steel sheet being a steel substrate made of an interstitially free (IF) alloy according to DIN EN 10 346 and a metallic coating arranged on one or both sides of the steel substrate, which in addition to zinc and unavoidable impurities Elements such as aluminum with a content of 0.5 to 8.0% by weight and magnesium with a content of 0.5 to 8.0% by weight in the coating. The invention further relates to a method for producing a hot-dip coated and tempered steel sheet and to a use.

When hot-dip refining with Al-containing zinc melts, an Al-containing oxide layer forms during the cooling process. When Mg is additionally added to the melt, the cooling process creates a layered structure of the oxide layer consisting of a substantially closed Mg oxide layer and Al oxides underneath. Due to the higher dipole moment, corresponding to the electronegativity difference of Mg oxide (ΔEN=2.27) compared to Al oxide (ΔEN=2.03) or zinc oxide (ΔEN=1.84), those applied to the Mg oxide layer become polarizable or dipolar compounds are more strongly bound to the surface. Typically, a corrosion protection system, for example an anti-corrosion oil, is applied to the oxide layer after hot-dip finishing. Since this adheres more strongly to Mg oxide due to the high dipole moment, the cleaning properties of the surface deteriorate. This has a negative impact on pre- and post-treatment processes, which require an oil and dirt-free surface. In particular, this leads to undesirable staining during phosphating.

Coatings made of zinc, aluminum and magnesium oxidize in air and form a covering, predominantly magnesium-rich oxide layer on the surface. This oxide layer has different chemical properties than established pure zinc or zinc-aluminum coatings. Further processing processes are aimed at established layers. When the chemical composition of the surface changes, the further processing properties also change. It is known from processing processes typical for automobiles that magnesium-rich surfaces are more difficult to join, clean and phosphate than established zinc-containing coatings. This limits the willingness of automobile manufacturers to use it in the body. In addition, extensive tests must be completed and passed.

Textured temper rolls transfer their texture during a tempering process to the surface of the steel sheets to be processed as a negative, ie elevations on the roll surface result in depressions in the steel sheet surface and vice versa. The temper impressions (recesses) introduced into the steel sheet surface in this way, so-called closed empty volumes, serve as lubricant pockets that hold a lubricant applied to the steel sheet surface and can carry it with them during the forming process. From the prior art, steel sheets dressed with a stochastic surface structure are exemplified in the patent specification EP 2 006 037 B1 and steel sheets tempered with a deterministic surface structure, for example from the patent specification EP 2 892 663 B1 known.

The surface chemistry of the contact surface can be changed due to the contact between the shaping elements of the temper roller and the steel sheet surface that occurs during the tempering process. In terms of chemistry, hot-dip coated coatings are constructed in such a way that a layer of alloying elements with a higher affinity for oxygen forms on the zinc that is primarily in the coating. The mechanical stress during tempering can ensure that zinc is exposed at the contact points between the tempering roller and the steel sheet instead of the alloying elements magnesium and/or aluminum. Hot-dip coated steel sheets that have been tempered with a stochastic surface structure have a different surface chemistry in the temper impressions of the coated steel sheet than on the elevations of the coated steel sheet. While the chemical composition in the skin pass impressions is richer in zinc, the elevations have high proportions of oxygen-affinous alloying elements (Mg and Al), cf. DE 10 2019 215 051 A1 .

Furthermore, from the EP 2 841 614 B1 It is known to condition or change the surface chemistry of hot-dip coated steel sheets by mechanical forces, such as brushing or blasting, in order to obtain better adhesive properties, in particular in order to essentially remove the native oxide layer.

In the EP 3 416 760 B1 It is disclosed that common specific rolling forces during skin pass are in the range of 1.9 kN/mm.

So-called interstitially free steels are also known, see also DIN EN 10346, which are used in the automotive sector and are particularly used in body components. An IF steel has no interstitially embedded alloying elements, meaning that no iron atoms are blocked by carbon or nitrogen atoms in the metal lattice. This creates a very soft steel with very good forming properties. It is primarily used for complicated deep-drawn parts in automobile construction. Steels of this type are available under the standard designation DX52D, DX55D, DX54D, DX55D, DX56D, DX57D HX160YD, HX180YD, HX220YD and HX260YD. These are cold-rolled steels.

The task is therefore to change the surface of hot-dip coated steel sheets in such a way that the product can be processed like established products.

The task is solved with the features of claim 1.

The inventors have found that the specific rolling force during tempering after hot-dip refining has an influence on the surface and thus also on the surface chemistry, such that by increasing the specific rolling force, a real enlarged surface can be produced compared to a perfectly flat surface. As part of the tempering process, the contact of the shaping elements of the tempering roll with the surface of the hot-dip coated steel sheet creates a mechanical stress, through which the thickness of > 0 up to 200 nm immediately below the magnesium-rich oxide layer (native oxide layer can be on the surface or near the surface, in particular up to 100 nm, preferably up to 50 nm, within the coating and is therefore to be understood as part of the coating) lying elements zinc and aluminum (oxide) can reach the surface of the coating. The specific rolling force, in particular its increase compared to the standard process, can be used to increase the surface area. This increase results from the fact that the Sdr value determined according to ISO 25178 is at least 1.8%. The Sdr value determined according to ISO 25178 corresponds to the percentage by which the real surface is larger than an absolutely flat surface due to the surface structure formed into the surface using tempering.

ISO 25178 takes into account measurements and specifications of three-dimensional surface textures (viewed on a defined surface) by defining three-dimensional texture parameters and the operators for determining them. It can also be used to record characteristic quantities such as the mean arithmetic height Sa in three dimensions, which was previously only possible in two dimensions by specifying the mean arithmetic roughness Ra on a line using ISO 4288, in particular along or across the rolling direction. In an alternative, the Sdr value is determined using confocal microscopy.

With an Sdr value of less than 1.80%, the influence on the surface chemistry is too small and would not subsequently lead to spot-free phosphating. High Sdr values of over 8.0% are possible, but can only be achieved with a lot of equipment and therefore with great effort, so that optimal, spot-free phosphating with an Sdr value between 1.80 and 8.0%, in particular at least 1.90%, 2.20%, 2.30%, 2.40%, preferably at least 2.50%, 2.70%, 2.80%, 3.0%, preferably at least 3.10% , 3.20%, 3.30%, 3.40%, 3.50% and in particular a maximum of 6.0%, preferably a maximum of 5.0%.

For the purposes of the invention, spots are defined as apparently dark areas (on the surface). A dark area is preferably delimited by dark points, which are characterized by the fact that they are darker than other, therefore brighter points in the immediate vicinity. In this sense, a point is not to be understood as a mathematical point, which has no extent, but rather, for example, as a pixel or group of pixels. Such a dark point only has a common boundary with lighter points in a partial area of its circumference. In the remaining part of its circumference it has a common border with dark points which have essentially the same brightness as this limiting dark point. An above-mentioned dark area therefore essentially consists of the latter dark points and the first-mentioned limiting dark points.

Steel sheets with a zinc-based coating have very good cathodic corrosion protection, which has been used in automobile construction for years. Since improved corrosion protection is provided, the coating has, in addition to zinc and unavoidable impurities, magnesium with a content of at least 0.5% by weight, in particular at least 0.8% by weight, preferably at least 1.1% by weight. on. In addition, aluminum is also present with a content of at least 0.5% by weight, in particular at least 0.8% by weight, preferably at least 1.1% by weight, in particular a To improve the connection of the coating to the steel sheet and in particular to essentially prevent a diffusion of iron from the steel sheet into the coating during heat treatment of the coated steel sheet, so that the positive corrosion properties are still retained. The thickness of the coating can be between 1 and 25 µm, in particular between 2 and 20 µm, preferably between 3 and 15 µm per side. Below the minimum limit, sufficient cathodic corrosion protection cannot be guaranteed and above the maximum limit, joining problems can occur when connecting the steel sheet according to the invention or a component made from it to another component. In particular, if the specified maximum limit of the coating thickness is exceeded, a stable process during thermal joining or welding cannot be ensured.

The mean arithmetic height Sa can be at least 0.70 μm, in particular at least 0.80 μm, preferably at least 0.90 μm. It can be limited to a maximum of 2.0 µm, in particular to a maximum of 1.80 µm, preferably to a maximum of 1.60 µm.

• C: 0,0003 bis 0,015%, insbesondere 0,0005 bis 0,010%, vorzugsweise 0,001 bis 0,005%;
• Si: 0,0005 bis 0,50%, insbesondere 0,0010 bis 0,40%, vorzugsweise 0,0010 bis 0,30%;
• Mn: 0,0005 bis 1,60%, insbesondere 0,010 bis 1,55%, vorzugsweise 0,010 bis 1,50%;
• P: bis 0,10%, insbesondere bis 0,080%, vorzugsweise 0,0002 bis 0,060%;
• S: bis 0,050%, insbesondere bis 0,040%, vorzugsweise 0,0003 bis 0,050%;
• N: bis 0,10%, insbesondere bis 0,080%, vorzugsweise 0,0001 bis 0,070%;
• AI: 0,0010 bis 1,0%, insbesondere 0,0010 bis 0,90%, vorzugsweise 0,0010 bis 0,80%;
• eine oder beide der folgenden Elemente:
  • Nb: 0,0001 bis 0,20%, insbesondere 0,0002 bis 0,10%, vorzugsweise 0,0003 bis 0,050%;
  • Ti: 0,0005 bis 0,20%, insbesondere 0,010 bis 0,150%, vorzugsweise 0,010 bis 0,120%;
  • optional eines oder mehrere folgender Elemente:
  • B bis 0,0050% und/oder Cu bis 0,20% und/oder Cr bis 0,20% und/oder Ni bis 0,20% und/oder Mo bis 0,150% und/oder Sn bis 0,10%;
  • Rest Eisen und unvermeidbare Verunreinigungen.

The IF alloy of the steel substrate contains or consists of the following elements in wt.%:

• C: 0.0003 to 0.015%, especially 0.0005 to 0.010%, preferably 0.001 to 0.005%;
• Si: 0.0005 to 0.50%, especially 0.0010 to 0.40%, preferably 0.0010 to 0.30%;
• Mn: 0.0005 to 1.60%, especially 0.010 to 1.55%, preferably 0.010 to 1.50%;
• P: up to 0.10%, especially up to 0.080%, preferably 0.0002 to 0.060%;
• S: up to 0.050%, especially up to 0.040%, preferably 0.0003 to 0.050%;
• N: up to 0.10%, especially up to 0.080%, preferably 0.0001 to 0.070%;
• Al: 0.0010 to 1.0%, especially 0.0010 to 0.90%, preferably 0.0010 to 0.80%;
• one or both of the following:
  • Nb: 0.0001 to 0.20%, especially 0.0002 to 0.10%, preferably 0.0003 to 0.050%;
  • Ti: 0.0005 to 0.20%, especially 0.010 to 0.150%, preferably 0.010 to 0.120%;
  • optionally one or more of the following elements:
  • B to 0.0050% and/or Cu to 0.20% and/or Cr to 0.20% and/or Ni to 0.20% and/or Mo to 0.150% and/or Sn to 0.10%;
  • Residual iron and unavoidable impurities.

The surface of the steel sheet can have a stochastic surface structure. This is created using temper rolls, the surfaces of which are textured in a so-called EDT process.

Alternatively, the surface of the steel sheet can have a deterministic surface structure. This is created using skin-pass rolls whose surfaces are textured with a laser.

A surface with a pseudo-stochastic surface structure would also be conceivable. These surface structures have a (quasi-) stochastic appearance, which are composed of stochastic elements with a recurring structure.

With an increase in the specific rolling force during skin pass and the associated increase in surface area, it was found that the standardized Mg content on the surface decreases, so that the Mg content is a maximum of 55%, in particular a maximum of 53%, preferably a maximum of 52%, preferably a maximum of 50 % amounts. The specification of the standardized proportion corresponds in particular to the determined mean, although fluctuations within the scope of measurement tolerances (standard deviation) may exist. It is not possible to fall below 10%. The Mg content on the surface can in particular be at least 15%, preferably at least 20%, preferably at least 25%.

Furthermore, it could also be observed that with an increase in the specific rolling force during tempering and the associated increase in surface area, the standardized Zn proportion on the surface increases, so that the Zn proportion is at least 13%, in particular at least 14%, preferably at least 15%. , preferably at least 17%. The specification of the standardized proportion corresponds in particular to the average value determined, although there were fluctuations within the scope of measurement tolerances (standard deviation). can. Exceeding 60% is not possible. The Zn content on the surface can in particular be a maximum of 50%, preferably a maximum of 40%, preferably a maximum of 35%.

The sum of the standardized proportions of magnesium, aluminum and zinc is always 100%.

The relative concentration of zinc, magnesium and aluminum is determined by determining the absolute concentration of these elements and then normalizing to 100%. The sum of the concentration of zinc, magnesium and aluminum is set equal to 100 and the proportion of the respective element in this 100% is evaluated or weighted as a relative concentration, i.e. based on 100%. The relative concentration of an element (Al, Mg, Zn) therefore refers to the sum of the concentrations of the elements Mg, Zn and Al, in that this sum represents 100%. Since the absolute concentration of the elements Zn, Mg and Al can vary from coating to coating, the information is given as a relative concentration in percentage points in order to precisely define changes. The occurrence of the elements zinc, magnesium and aluminum within the meaning of the invention is recorded regardless of the form in which they are present. It therefore does not matter whether these elements are present as neutral atoms or as ions, in a compound such as an alloy or intermetallic phases or in a compound such as complexes, oxides, salts, hydroxides or the like. Thus, the terms “zinc”, “aluminum” and “magnesium” in the sense of the invention can cover not only the elements in pure form, but also oxidic and/or hydroxide or any form of compounds that contain these elements.

The tendency for spot formation during phosphating decreases with decreasing normalized Mg content and with increasing normalized Zn content on the surface.

The relative concentration differences in magnesium, aluminum and zinc on the surface of the coating, i.e. on the “native” (magnesium-rich) oxide layer, can be determined by recording the local distribution of the signals for these alloying elements using a time-of-flight secondary ion mass spectrometer. Flight Secondary Ion Mass Spectrometry, ToF-SIMS) in imaging mode or similarly using Auger electron or photoelectron spectroscopy. ToF-SIMS is an analysis method for determining the chemical surface composition of the top 1-3 monolayers.

Using ToF-SIMS, certain relative concentration differences are measured by scanning the surface to be analyzed within a representative measuring area. A spectrum in the positive polarity is recorded at each position of the grid and the raw signals for the main components (alloy elements) are recorded. The relative concentration of the element Raw signal integral)], where the denominator of the quotient is the sum of the raw signal integrals of all alloying elements in the coating. “Raw signal” of element X in this definition is the intensity or peak area of element X in the mass spectrum or “raw signal integral” of element X is assigned. The ToF-SIMS characterization can be carried out in a measuring area of 200x200 µm ² or 500x500 µm ² . The internal ToF-SIMS measurements can be carried out using a TOF.SIMS 5 device from ION-TOF GmbH.

The near-surface chemical composition is determined, for example, using X-ray photoelectron spectroscopy (XPS), the procedure for determining the individual chemical compositions being known from the prior art. For the purposes of the invention, the XPS-typical information depth corresponds to a layer with a thickness of essentially 5 nm. The measurement can be carried out, for example, with the Phi Quantera II SXM Scanning XPS Microprobe device from Physical Electronics GmbH. The element concentrations measured using ^the As described above, normalization to 100% is carried out to indicate the relative concentrations.

In the sense of the invention, the term essentially means in relation to a feature or a process that this feature or process is almost completely fulfilled, but there remains a difference of a maximum of 50%, 45%, 40%, preferably 30%, 25% , particularly preferably 20%, 19%, 18%, 17%, 16%, 15%, 14%, 13%, 12%, 11%, especially 10%, 9%, 8%, 7%, 6%, 5%, 4%, 3%, 2%, 1% or 0.5% , 0.1% to 100% agreement.

Sheet steel is generally understood to mean a cold-rolled flat steel product, which can be provided in sheet form or in blank form or in strip form. The thickness of the steel sheet can be between 0.45 and 2.5 mm, in particular at least 0.5 mm, preferably at least 0.6 mm and in particular a maximum of 2.0 mm, preferably a maximum of 1.8 mm.

According to a second aspect, the invention relates to a method for producing a hot-dip-finished and tempered steel sheet, comprising the following steps: - providing a steel substrate made of an interstitially-free alloy according to DIN EN 10346, - hot-dip finishing of the steel substrate on one or both sides with a metallic coating, which in addition Zinc and unavoidable impurities additional elements such as aluminum with a content of 0.5 to 8.0% by weight and magnesium with a content of 0.5 to 8.0% by weight in the coating, - tempering the hot-dip-finished steel sheet, whereby a skin-passing force during skin-passing is adjusted in such a way that a surface Sdr value of at least 1.80% results on the surface of the hot-dip-coated and skin-passed steel sheet, determined in accordance with ISO 25178.

The surface (positive shape) of the tempering roller forms a surface structure by applying force to the surface of the steel sheet, which defines depressions (negative shape) and essentially corresponds to the surface with elevations (positive shape) of the tempering roller. The set specific rolling force can have a positive influence by essentially displacing the surface chemistry and essentially the oxygen-affinous alloying elements such as magnesium and aluminum on the surface of the coating through the application of force during tempering and also by increasing the surface area. Since magnesium has a higher affinity for oxygen than aluminum, a magnesium-rich oxide layer forms on the surface in the coating or near the surface, particularly during hot-dip refining. The force can essentially be used to essentially displace disruptive layers, such as the magnesium-rich oxide layers, so that zinc and optionally aluminum increase in relative concentration on the surface, which in turn results in a stain-free surface during post-treatment and thus during phosphating can lead.

In order to avoid repetition, reference is made to the statements on the hot-dip coated and tempered steel sheet according to the invention.

In order in particular to reduce the relative concentration of magnesium on the surface of the coating in the valley areas or to displace the magnesium-rich oxide layer, according to one embodiment of the method according to the invention, a specific rolling force during tempering of at least 1.8 kN / mm is set, so that the surface can be increased. A further increase is possible if a specific rolling force during tempering is set, in particular at least 2.0 kN/mm, preferably at least 2.2 kN/mm, preferably at least 2.3 kN/mm. Specific rolling forces above 10 kN/mm do not bring any advantage and only increase manpower and equipment costs. In addition, the abrasion or wear generated during skin pass due to the shear forces between the sheet metal and skin pass roll surface outside the flow divide increases with the specific rolling force.

In a further embodiment, the hot-dip coated and tempered steel sheet described above is oiled with a mineral oil-based corrosion inhibitor. Mineral oils and mineral oil-based corrosion inhibitors are known to those skilled in the art. Mineral oils are made from coal, peat, wood, petroleum or natural gas and, unlike oils from organisms, contain essentially no fatty acid triglycerides. Corrosion inhibitors based on mineral oil contain or consist of over 50%, preferably over 70%, particularly preferably over 90%, mineral oils, as well as optionally other additives and/or so-called synthetic oils which have a special molecular structure, as in this form in the starting material (for example Crude oil) does not occur.

The expert knows what is meant by specific rolling force during skin pass. The specific rolling force is the absolute rolling force in N divided by the strip width in mm.

According to a third aspect, the invention relates to a use of a hot-dip coated and tempered steel sheet according to the invention, which has been produced in particular by the method according to the invention, for parts in vehicle construction, preferably for outer skin parts on the vehicle.

Samples were separated from a cold-rolled steel substrate of grade DX56D with a thickness of 0.7 mm, which were hot-dip coated on a laboratory scale with different metallic coatings and tempered with different temper parameters and submitted to further investigations. The results are summarized in Table 1. The thickness of the coating (including the oxide layer) was 6 µm per side. Samples 1, 2 and 4 were tempered with a pair of temper rolls with a stochastic surface texture and samples 5, 7 and V8 were tempered with a pair of temper rolls with a deterministic surface texture. Samples V3, V6, V9 and V10 were conventionally tempered with a pair of temper rolls with a stochastic surface texture. Table 1 sample spec. Walz. [kN/mm] Coating [% by weight], balance Zn and impurities XPS relative [%], Mg+Al+Zn=100% Sdr [%]; Sa [µm] stains 1 2.31 Mg: 2.0%, Al: 1.7% Mg=38%, Al=35%, Zn=27% 2.19; 1.02 no 2 2.69 Mg: 2.0%, Al: 1.7% Mg=36%, Al=34%, Zn=30% 2.45; 1.12 no V3 1.5 Mg: 1.2%, Al: 0.4% Mg=62%, Al=16%, Zn=22% 1.61; 0.99 Yes 4 2.86 Mg: 1.4%, Al: 1.8% Mg=34%, Al=32%, Zn=34% 2.63; 1.31 no 5 3.55 Mg: 1.4%, Al: 1.8% Mg=28%, Al=33%, Zn=39% 4.2; 1.42 no V6 1.61 Mg: 5.7%, Al: 6.1% Mg=52%, Al=48%, Zn=6% 1.51; 0.95 Yes 7 3.2 Mg: 5.7%, Al: 6.1% Mg=57%, Al=42%, Zn=21% 2.5; 1.21 no V8 3.45 Mg: 9.3%, Al: 10.2% Mg=57%, Al=33%, Zn=10% 3.11; 1.39 Yes V9 1.21 Mg: 1.8%, Al: 1.2% Mg=48%, Al=43%, Zn=9% 0.78; 0.67 Yes V10 1.35 Mg: 1.8%, Al: 1.2% Mg=50%, Al=43%, Zn=7% 0.87; 0.71 Yes

In all samples, the oxide layer thickness was < 60 nm. It can be clearly seen that the tempering process essentially influences the surface chemistry of a steel sheet hot-dip coated with a Mg-Al-Zn coating, in such a way that with an increase in the specific rolling force and the resulting Due to the associated increase in surface area, the surface chemistry can also be adjusted positively by reducing the magnesium-rich components.

All samples then went through the following process stages: oiling with a mineral oil-based corrosion inhibitor, degreasing, cleaning, rinsing, activating, rinsing, phosphating, rinsing and drying. These process stages were carried out conventionally using means familiar to those skilled in the art. The phosphated samples were visually inspected, with samples V6 and V8 to V10 showing very distinctive and conspicuous spots. Further investigations had shown that in the dark areas an average crystal size of the phosphate-containing crystals (so-called phosphate crystals) of (5+/-2) µm was significantly exceeded in mean value and its standard deviation.

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 2006037 B1 [0004]
• EP 2892663 B1 [0004]
• DE 102019215051 A1 [0005]
• EP 2841614 B1 [0006]
• EP 3416760 B1 [0007]

Claims (11)

Steel sheet, which is hot-dip refined and tempered, the steel sheet being a steel substrate made of an interstitially free alloy according to DIN EN 10346 and a metallic coating arranged on one or both sides of the steel substrate, which, in addition to zinc and unavoidable impurities, contains additional elements such as aluminum with a content of 0 .5 to 8.0% by weight and magnesium with a content of 0.5 to 8.0% by weight in the coating, characterized in that the hot-dip coated and tempered steel sheet has a surface with a according to ISO 25178 has a Sdr value of at least 1.80%. sheet steel Claim 1 , where the IF alloy of the steel substrate contains or consists of the following elements in wt.%: C: 0.0003 to 0.0150%; Si: 0.0005 to 0.50%; Mn: 0.020 to 1.60%; P: up to 0.10%; S: up to 0.050%; N: up to 0.10%; Al: 0.010 to 1.0%; one or both of the following: Nb: 0.0001 to 0.20%; Ti: 0.0005 to 0.20%; optionally one or more of the following elements: B: up to 0.0050% and/or Cu: up to 0.20% and/or CR: up to 0.20% and/or Ni: up to 0.20% and/or Mon: up to 0.150% and/or Sn: up to 0.10%; Residual iron and unavoidable impurities. sheet steel Claim 1 , where the surface has a stochastic surface structure. sheet steel Claim 1 , where the surface has a deterministic surface structure. sheet steel Claim 1 , where the surface has a pseudo-deterministic surface structure. Steel sheet according to one of the preceding claims, wherein the surface has a relative Mg content of a maximum of 55%, the sum of the relative proportions of magnesium, aluminum and zinc being 100%, determined using XPS. Steel sheet according to one of the preceding claims, wherein the surface has a relative Zn content of at least 13%, the sum of the relative proportions of magnesium, aluminum and zinc being 100%, determined using XPS. Process for producing a hot-dip coated and tempered steel sheet, comprising the following steps: - providing a steel substrate made of an interstitially free alloy according to DIN EN 10346, - hot-dip finishing of the steel substrate on one or both sides with a metallic coating which, in addition to zinc and unavoidable impurities, contains additional elements such as aluminum with a content of 0.5 to 8.0% by weight and magnesium with a content of 0.5 to 8.0% by weight in the coating, - tempering the hot-dip coated steel sheet, characterized in that a Tempering force during tempering is adjusted in such a way that the surface of the hot-dip coated and tempered steel sheet has a surface Sdr value of at least 1.80%, determined in accordance with ISO 25178. Procedure according to Claim 8 , whereby the skin pass force is set to at least 1.8 kN/mm. Procedure according to Claim 8 or 9 , whereby the hot-dip coated and tempered steel sheet is oiled with a mineral oil-based corrosion inhibitor. Use of a hot-dip refined and tempered steel sheet according to one of the Claims 1 until 7 , especially made according to one of the Claims 8 until 10 , for parts in vehicle construction.