Method for the hot-dip coating of a flat steel product containing 2-35 wt.% of Mn, and a flat steel product

The invention claimed is: 1. A flat steel product comprising a steel substrate having an Mn content of 2-35 wt. % and a Zn protective coating formed by zinc or a zinc alloy which provides protection against corrosion, wherein the protective Zn coating comprises a layer of Mn mixed oxide which substantially covers and adheres to the flat steel product and a layer of Zn which shields the flat steel product and the layer of Mn mixed oxide adhering thereto from the surroundings and wherein the Mn mixed oxide is MnO.Fe Metal . 2. The flat steel product according to claim 1 , wherein the protective Zn coating further comprises a layer of FeMn 2 Al 5 arranged between the layer of Mn mixed oxide and the layer of Zn. 3. The flat steel product according to claim 1 , wherein the protective Zn coating further comprises a layer of FeMnZn which is situated between the layer of Mn mixed oxide and the layer of Zn. 4. The flat steel product according to claim 1 , wherein the protective Zn coating takes the form of a coating of ZnMg alloy. 5. The flat steel product according to claim 1 , wherein the flat steel product is produced by a method comprising: a) providing the flat steel product; b) annealing the flat steel product; at an annealing temperature Ta of 600-1100*C, for an annealing time of 10-240 s under an annealing atmosphere which has a reducing effect on the FeO present on the flat steel product and an oxidising effect on the Mn contained in the steel substrate and which annealing atmosphere contains 0.01-85 vol. % of H2, H 2 O and the remainder N 2 and unavoidable impurities present for technical reasons and which has a dew point lying between −70° C. and +60° C., the H 2 O/H2 ratio being: 8·10 −15 −x T a 3.529 <H 2 O/H2≦0.957, thereby producing on the flat steel product a 20-400 nm thick layer of MnO.Fe Metal which covers the flat steel product at least in sections, c) cooling the annealed flat steel product to a temperature for bath entry; d) conveying the flat steel product which has been cooled to the temperature for bath entry through a bath of molten Zn saturated within iron and which is at a temperature of 420-520° C., within a dip time of 0.1-10 s, the flat steel product thus being hot-dip coated with a protective coating of Zn providing protection against corrosion, the bath of molten Zn containing, as well as the main constituent zinc and unavoidable impurities, 0.05-8 wt. % of Al and/or up to 8 wt. % of Mg, and, optionally, Si<2%, Pb<0.1%, Ti<0.2%, Ni<1%, Cu<1%, Co<0.3%, Mn<0.5%, Cr<0.2%, Sr<0.5%, Fe<3%, B<0.1%, Bi<0.1%, Cd<0.1%; and, e) cooling the flat steel product provided with the Zn coating which emerges from the bath of molten metal. 6. A method for producing the flat steel according to claim 1 , comprising: a) providing the flat steel product; b) annealing the flat steel product; at an annealing temperature Ta of 600-1100*C, for an annealing time of 10-240 s under an annealing atmosphere which has a reducing effect on the FeO present on the flat steel product and an oxidising effect on the Mn contained in the steel substrate and which annealing atmosphere contains 0.01-85 vol. % of H2, H 2 O and the remainder N 2 and unavoidable impurities present for technical reasons and which has a dew point lying between −70° C. and +60° C., the H 2 O/H2 ratio being: 8·10 −15 −x T a 3.529 <H 2 O/H2≦0.957, thereby producing on the flat steel product a 20-400 nm thick layer of MnO.Fe Metal which covers the flat steel product at least in sections, c) cooling the annealed flat steel product to a temperature for bath entry; d) conveying the flat steel product which has been cooled to the temperature for bath entry through a bath of molten Zn saturated within iron and which is at a temperature of 420-520° C., within a dip time of 0.1-10 s, the flat steel product thus being hot-dip coated with a protective coating of Zn providing protection against corrosion, the bath of molten Zn containing, as well as the main constituent zinc and unavoidable impurities, 0.05-8 wt. % of Al and/or up to 8 wt. % of Mg, and, optionally, Si<2%, Pb<0.1%, Ti<0.2%, Ni<1%, Cu<1%, Co<0.3%, Mn<0.5%, Cr<0.2%, Sr<0.5%, Fe<3%, B<0.1%, Bi<0.1%, Cd<0.1%; and, e) cooling the flat steel product provided with the Zn coating which emerges from the bath of molten metal. 7. The method according to claim 6 , wherein the flat steel product is made available in the form of a cold-rolled steel strip. 8. The method according to claim 6 , wherein the annealing is preceded by an annealing step in which the flat steel product is kept at an annealing temperature of 200-1100° C. for an annealing time of 0.1 to 60 s under an atmosphere which is oxidative to Fe and Mn and which contains 0.0001-5 vol. % of H2 and, optionally, 200-5500 vol. ppm of O2 and which has a dew point in the range from −60° C. to +60° C. 9. The method according to claim 6 , wherein the thickness of the layer of MnO.Fe Metal obtained after annealing is 40-400 nm. 10. The method according to claim 6 , wherein the layer of MnO.Fe Metal substantially covers the whole of the surface of the flat steel product after the annealing of the flat steel product. 11. The method according to claim 6 , wherein the dip time in the bath of molten Zn is 0.1-5 s. 12. The method according to claim 6 , wherein the bath of molten Zn contains both Al and Mg. 13. The method according to claim 12 , wherein the Al content of the bath is smaller than the Mg content thereof. 14. The method according to claim 6 , wherein the temperature for bath entry of the flat steel product is 360-710° C.