SURFACE-FINISHED STEEL SHEET AND METHOD FOR THE PRODUCTION THEREOF

Abstract

A surface-finished steel sheet, in some examples cold-rolled thin steel sheet, includes a metallic corrosion-resistant layer that may comprise more than 40% by weight aluminum and iron. So that that corrosion-resistant layer has high formability, especially cold formability, and hence significantly improved adhesion on forming, the corrosion-resistant layer may comprises nickel, wherein nickel-containing phases are located at a transition from the corrosion-resistant layer to a base material of the steel sheet. The nickel content of the corrosion resistant layer may be in a range from 5 to 30% by weight. Further, a method for producing a surface-finished steel sheet of this kind is also disclosed. In some examples, a nickel layer may be applied to a steel sheet, preferably cold-rolled thin steel sheet in the form of flat steel product, prior to hot-dip coating the steel sheet with a liquid aluminum melt or with a liquid melt of aluminum-based alloy.

Claims

1.-16. (canceled)

17. A surface-finished steel sheet comprising a metallic corrosion-resistant layer that comprises: more than 40% by weight aluminum; iron; and 5 to 30% by weight nickel, wherein nickel-containing phases are located at a transition from the metallic corrosion-resistant layer to a base material of the surface-finished steel sheet.

18. The surface-finished steel sheet of claim 17 wherein the metallic corrosion-resistant layer further comprises silicon.

19. The surface-finished steel sheet of claim 18 wherein the metallic corrosion-resistant layer comprises less than 8% by weight silicon.

20. The surface-finished steel sheet of claim 18 wherein the metallic corrosion-resistant layer comprises less than 5% by weight silicon.

21. The surface-finished steel sheet of claim 17 wherein an outer half layer of the metallic corrosion-resistant layer contains more nickel than iron.

22. The surface-finished steel sheet of claim 17 wherein the base material is cold-rolled thin steel sheet.

23. The surface-finished steel sheet of claim 17 wherein the base material is press-hardenable steel.

24. The surface-finished steel sheet of claim 17 wherein the metallic corrosion-resistant layer comprises intermetallic AlNi phases.

25. The surface-finished steel sheet of claim 17 wherein the metallic corrosion-resistant layer has a thickness in a range from 8 to 20 μm.

26. The surface-finished steel sheet of claim 17 wherein the metallic corrosion-resistant layer has a thickness in a range from 10 to 15 μm.

27. The surface-finished steel sheet of claim 17 wherein the metallic corrosion-resistant layer comprises more than 50% by weight aluminum.

28. The surface-finished steel sheet of claim 17 wherein the metallic corrosion-resistant layer comprises 10 to 25% by weight nickel.

29. A method for producing a steel sheet surface-finished with a metallic corrosion-resistant layer, the method comprising: applying a nickel layer to a flat steel product; and hot-dip coating the flat steel product with aluminum or an aluminum-based alloy after the nickel layer is applied to the flat steel product.

30. The method of claim 29 wherein the nickel layer applied to the flat steel product has a thickness in a range from 1 to 5 μm.

31. The method of claim 29 wherein the nickel layer is applied to the flat steel product by way of an electrolytic coating operation.

32. The method of claim 31 wherein a nickel electrolyte used for the electrolytic coating operation is based on nickel sulfate and nickel chloride.

33. The method of claim 29 further comprising subjecting the flat steel product with the nickel layer to a recrystallizing annealing treatment under inert gas before hot-dip coating the flat steel product.

34. The method of claim 29 wherein the hot-dip coating is carried out such that a resultant corrosion-resistant layer comprises aluminum, iron, and nickel and has a layer thickness in a range from 8 to 20 μm.

35. The method of claim 29 wherein a melt bath used for the hot-dip coating comprises a pure aluminum melt and unavoidable impurities.

36. The method of claim 29 wherein a melt bath used for the hot-dip coating comprises an aluminum melt with up to 10% by weight silicon.

Description

[0021] The invention is elucidated in more detail below by exemplary embodiments, with reference to the appended figures, of which:

[0022] FIG. 1 shows an element depth profile, determined by glow discharge spectroscopy (GDOES), of a steel sheet coated in accordance with the invention; and

[0023] FIG. 2 shows cold-drawn cups, the left-hand cup having been produced from a steel sheet bearing a conventional AlSi covering, and the right-hand cup from a steel sheet bearing an Al—Ni covering of the invention.

[0024] To produce a steel sheet surface-finished with a metallic corrosion-resistant layer, cold-rolled thin sheet strip having a metal-sheet thickness of approximately 1.25 mm was provided, in a continuous electrolytic coating operation, with a nickel layer around 3 μm thick or, in one variant, with a nickel layer around 1 μm thick. For this purpose, in each case, a Watts nickel electrolyte was used, based on nickel sulfate and nickel chloride. This coating operation may also be referred to as an electroplating operation. Cold-rolled thin sheet strip used in each case was a steel strip (base material) of grade 22MnB5.

[0025] The electrolytically nickel thin-coated sheet strip was next passed on for annealing treatment in a continuous hot-dip coating unit. In the continuous oven upstream of the coating bath in the hot-dip coating unit, the nickel-precoated fine sheet strip was given a recrystallizing anneal under an atmosphere of inert gas or forming gas (about 95% nitrogen, 5% hydrogen, dew point −30° C.). After a hold time of 60 seconds at a temperature of around 800° C., the annealed fine sheet strip was cooled to a bath dip temperature of around 705° C. and then guided through the coating bath. In one preferred variant, the coating bath consisted substantially of pure liquid aluminum melt. In another variant, the coating bath used consisted of an aluminum melt containing about 10 wt % of silicon. The layer thickness of the aluminum covering or AlSi covering applied in this way was adjusted, by means of scraping nozzles disposed above the coating bath, such that the layer thickness of the metallic corrosion-resistant layer formed from the nickel layer and the hot-dip covering was approximately 10 μm. This metallic corrosion-resistant layer may also be referred to as an aluminum-nickel alloy layer.

[0026] FIG. 1 shows the composition of a corrosion-resistant layer of the invention, obtained after the hot-dip coating operation, on a steel sheet having undergone preliminary nickel-coating, on the basis of an element depth profile. The dashed line shows the nickel content in wt % relative to the depth of the metallic corrosion-resistant layer. The line beginning at the bottom left and rising almost to 100 wt % indicates the Fe content of the corrosion-resistant layer relative to its depth, while the third line relates to the Al content.

[0027] It is apparent that in this example, the nickel content close to the surface of the corrosion-resistant layer is in the range from 10 to 12 wt %. In the direction of the cold-rolled thin sheet, the nickel content of the approximately 10 μm thick corrosion-resistant layer increases to about 19 to 20 wt % at a depth of up to about 6 μm. Thereafter the nickel content of the corrosion-resistant layer gradually drops in the direction of the coated thin sheet.

[0028] The aluminum content of the corrosion-resistant layer exhibits its maximum close to the surface of the layer. In the case of this example, the maximum Al content is situated in the range from about 82 to 86 wt %. The nickel coating (preliminary nickel coating) has suppressed the iron content of the aluminum, giving the covering a much lower brittleness or much greater ductility than the known AlSi covering. In FIG. 1 it can be seen that the nickel content in the outer layer half of the corrosion-resistant layer is much greater than the iron content.

[0029] For evaluating the formability of the corrosion-resistant layer of the invention, cold-rolled thin steel sheets of grade 22MnB5, coated accordingly, were subjected to cold forming, specifically by deep-drawing to form circular cups, and the adhesion of their coverings was compared, on the basis of the appearance of the corrosion-resistant layer, with that of a known Al—Si hot-dip covering (as reference) and also of a known Al hot-dip covering (see table). Furthermore, sample production was varied by producing different nickel layer thicknesses and by investigating samples without preliminary nickel coating as well.

[0030] The table shows that by means of a sufficiently thick nickel layer, it is possible to increase significantly the ductility and adhesion of the covering (corrosion-resistant layer) on cold forming relative to that of known AlSi and Al hot-dip coverings (samples 1 and 4). The photographs in FIG. 2 provide further illustration of this.

[0031] The left-hand cup in FIG. 2 was produced by cold deep-drawing of a thin steel sheet bearing a conventional AlSi covering. The right-hand cup, in contrast, was produced by cold deep-drawing of a thin steel sheet having an Al—Ni covering of the invention. Whereas the left-hand cup exhibits significant delamination of the AlSi covering in the forming-stressed region of the cup, no instances of delamination can be ascertained on the right-hand cup.

[0032] The corrosion-resistant layer of the invention is therefore distinguished by significantly increased ductility and at the same time by significantly enhanced adhesion in cold forming. In addition, the corrosion-resistant layer of the invention further possesses the property of scale protection afforded by the known AlSi covering for hot forming. The corrosion-resistant layer of the invention is therefore likewise suitable for hot forming. The advantages of the present invention can be utilized also in particular when producing components by roll profiling and subsequent hardening.

TABLE-US-00001 TABLE Comparison of covering adhesion/cold formability In accordance Sample Designation Adhesion of with No. of covering Production covering invention 1 AlSi Al melt with 10 wt % Si Poor, severe no (Reference) delaminations 2 AlNi 3 μm preliminary Ni Very good, no yes coating hot-dip coated delaminated with pure aluminum areas 3 AlNi 1 μm preliminary Ni Good, but slight yes coating hot-dip coated delaminations with pure aluminum apparent 4 AlFe Without preliminary Ni Poor, severe no coating hot-dip coated delaminations with pure aluminum apparent 5 AlSiNi 3 μm preliminary Ni Good, but slight yes coating hot-dip coated delaminations with AlSi apparent