Method for producing steel composite materials

The invention claimed is: 1. A method for producing a steel composite characterized by: placing at least two steel sheets of different steel grades selected from material 1 and material 2 against each other in an alternating structure; hot rolling the steel sheets together, and optionally cold rolling, to create the steel composite; and diffusion annealing the steel composite at an annealing temperature of 650° C. to 720° C. wherein: the annealing temperature is below the minimum of Ac1 temperature of the material 1 and Ac1 temperature of the material 2; a chemical potential of the material 1 (μ C, material 1 ) and a chemical potential of the material 2 (μ C, material 2 ) at the annealing temperature correspond to the equation: μ C, material 1 >μ C, material 2 ; material 1 has a lower carbon content than material 2, so that an uphill diffusion of carbon takes place between material 1 and material 2; material 1 has an alloy composition, in mass percent, of: carbon (C): 0.02-0.12, manganese (Mn): 0.2-1.2, aluminum (Al): 0.01-0.07, silicon (Si): <0.5, chromium (Cr): <0.3, titanium (Ti): 0.01-0.15, nitrogen (N): <0.02, boron (B): <0.02, phosphorus (P): <0.01, sulfur (S): <0.01, molybdenum (Mo): <1, and balance being iron and smelting impurities; and material 2 has an alloy composition, in mass percent, of: carbon (C): 0.08-0.6, manganese (Mn): 0.8-3.0, aluminum (Al): 0.01-0.07, silicon (Si): 0.01-0.5, chromium (Cr): 0.02-0.6, titanium (Ti): 0.01-0.08, nitrogen (N): <0.02, boron (B): 0.002-0.02, phosphorus (P): <0.01, sulfur (S): <0.01, molybdenum (Mo): <1, and balance being iron and smelting impurities. 2. The method according to claim 1 , characterized by: a difference between the chemical potential of the material 1 (μ C, material 1 ) and the chemical potential of the material 2 (μ C, material 2 ) at the annealing temperature being greater than 500 J/mol. 3. The method according to claim 1 , characterized by: the at least two steel sheets consisting of three steel sheets in an A-B-A structure or a B-A-B structure, wherein A represent steel sheet of steel grade material 1 and B represent steel sheet of steel grade material 2. 4. The method according to claim 3 , characterized by: each of the two outer steel sheets in the A-B-A structure or the B-A-B structure making up at most-25% of the total thickness of the steel composite. 5. The method according to claim 1 , characterized by: providing at least one side of the steel composite with a metallic coating selected from the group consisting of aluminum, an alloy containing essentially aluminum, an alloy composed of aluminum and zinc, a zinc alloy containing essentially zinc.