Copper-nickel-tin alloy, method for the production thereof and use thereof

1 . A high-strength copper-nickel-tin alloy having excellent castability, hot formability and cold formability, high resistance to abrasive wear, adhesive wear and fretting wear, and improved corrosion resistance and stress relaxation resistance, consisting of (in % by weight): 2.0% to 10.0% Ni, 2.0% to 10.0% Sn, 0.01% to 1.5% Si, 0.002% to 0.45% B, 0.001% to 0.09% P, optionally up to a maximum of 2.0% Co, optionally up to a maximum of 2.0% Zn, optionally up to a maximum of 0.25% Pb, balance: copper and unavoidable impurities, characterized in that the Si/B ratio of the element contents in % by weight of the elements silicon and boron is a minimum of 0.4 and a maximum of 8; the copper-nickel-tin alloy includes Si-containing phases and B-containing phases and phases of the systems Ni—Si—B, Ni—B, Ni—P and Ni—Si that significantly improve the processing properties and use properties of the alloy. 2 . A high-strength copper-nickel-tin alloy having excellent castability, hot formability and cold formability, high resistance to abrasive wear, adhesive wear and fretting wear, and improved corrosion resistance and stress relaxation resistance, consisting of (in % by weight): 2.0% to 10.0% Ni, 2.0% to 10.0% Sn, 0.01% to 1.5% Si, 0.002% to 0.45% B, 0.001% to 0.09% P, optionally up to a maximum of 2.0% Co, optionally up to a maximum of 2.0% Zn, optionally up to a maximum of 0.25% Pb, balance: copper and unavoidable impurities, characterized in that the Si/B ratio of the element contents in % by weight of the elements silicon and boron is a minimum of 0.4 and a maximum of 8; the following microstructure constituents are present in the alloy after casting: a) an Si-containing and P-containing metallic base composition having, based on the overall microstructure, a1) up to 35% by volume of first phase constituents that can be reported by the empirical formula Cu h Ni k Sn m and have an (h+k)/m ratio of the element contents in atom % of 2 to 6, a2) up to 15% by volume of second phase constituents that can be reported by the empirical formula Cu p Ni r Sn s and have a (p+r)/s ratio of the element contents in atom % of 10 to 15 and a3) a balance of solid copper solution; b) phases which, based on the overall microstructure, are present b1) at 0.01% to 10% by volume as Si-containing and B-containing phases, b2) at 1% to 15% by volume as Ni—Si borides having the empirical formula Ni x Si 2 B with x=4 to 6, b3) at 1% to 15% by volume as Ni borides, b4) at 1% to 5% by volume as Ni phosphides, b5) at 1% to 5% by volume as Ni silicides in the microstructure, which are present individually and/or as addition compounds and/or mixed compounds and are ensheathed by tin and/or the first phase constituents and/or the second phase constituents; in the course of casting the Si-containing and B-containing phases in the form of silicon borides, the Ni—Si borides and the Ni borides, Ni phosphides and Ni silicides that are present individually and/or as addition compounds and/or mixed compounds constitute seeds for uniform crystallization during the solidification/cooling of the melt, such that the first phase constituents and/or the second phase constituents are distributed uniformly in the microstructure like islands and/or like a mesh; the Si-containing and B-containing phases that are in the form of boron silicates and/or boron phosphorus silicates, together with the phosphorus silicates, assume the role of a wear-protecting and corrosion-protecting coating on the semifinished materials and components of the alloy. 3 . A high-strength copper-nickel-tin alloy having excellent castability, hot formability and cold formability, high resistance to abrasive wear, adhesive wear and fretting wear, and improved corrosion resistance and stress relaxation resistance, consisting of (in % by weight): 2.0% to 10.0% Ni, 2.0% to 10.0% Sn, 0.01% to 1.5% Si, 0.002% to 0.45% B, 0.001% to 0.09% P, optionally up to a maximum of 2.0% Co, optionally up to a maximum of 2.0% Zn, optionally up to a maximum of 0.25% Pb, balance: copper and unavoidable impurities, characterized in that the Si/B ratio of the element contents in % by weight of the elements silicon and boron is a minimum of 0.4 and a maximum of 8; after the further processing of the alloy by at least one annealing operation or by at least one hot forming operation and/or cold forming operation, as well as at least one annealing operation, the following microstructure constituents are present: A) a metallic base composition having, based on the overall microstructure, A1) up to 15% by volume of first phase constituents that can be reported by the empirical formula Cu h Ni k Sn m and have an (h+k)/m ratio of the element contents in atom % of 2 to 6, A2) up to 5% by volume of second phase constituents that can be reported by the empirical formula Cu p Ni r Sn s and have a (p+r)/s ratio of the element contents in atom % of 10 to 15 and A3) a balance of solid copper solution; B) phases which, based on the overall microstructure, are present B1) at 2% to 30% by volume as Si-containing and B-containing phases, Ni—Si borides having the empirical formula Ni x Si 2 B with x=4 to 6, as Ni borides, Ni phosphides and as Ni silicides in the microstructure, which are present individually and/or as addition compounds and/or mixed compounds and are ensheathed by precipitates of the (Cu, Ni)—Sn system, B2) at up to 80% by volume as continuous precipitates of the (Cu, Ni)—Sn system in the microstructure, B3) at 2% to 30% by volume as Ni phosphides and Ni silicides in the microstructure that are present individually and/or as addition compounds and/or mixed compounds, are ensheathed by precipitates of the (Cu, Ni)—Sn system and have a size of less than 3 μm; the Si-containing and B-containing phases that are in the form of silicon borides, the Ni—Si borides and the Ni borides, Ni phosphides and Ni silicides that are present individually and/or as addition compounds and/or mixed compounds constitute seeds for static and dynamic recrystallization of the microstructure during the further processing of the alloy, which enables the establishment of a uniform and fine-grain microstructure; the Si-containing and B-containing phases that are in the form of boron silicates and/or boron phosphorus silicates, together with the phosphorus silicates, assume the role of a wear-protecting and corrosion-protecting coating on the semifinished materials and components of the alloy. 4 . The copper-nickel-tin alloy as claimed in claim 1 , characterized in that the elements nickel and tin are each present at 3.0% to 9.0%. 5 . The copper-nickel-tin alloy as claimed in claim 1 , characterized in that the element silicon is present at 0.05% to 0.9%. 6 . The copper-nickel-tin alloy as claimed in claim 1 , characterized in that the element boron is present at 0.01% to 0.4%. 7 . The copper-nickel-tin alloy as claimed in claim 1 , characterized in that the element phosphorus is present at 0.01% to 0.09%. 8 . The copper-nickel-tin alloy as claimed in claim 1 , characterized in that the alloy is free of lead apart from any unavoidable impurities. 9 . A process for producing end products or components in near-end-product form from a copper-nickel-tin alloy as claimed in claim 1 with the aid of the sandcasting process, the shell mold casting process, precision casting process, full mold casting process, pressure diecasting process or lost foam process. 10 . A process for producing strips, sheets, plates, bolts, round wires, profile wires, round bars, profile bars, hollow bars, pipes and profiles from a copper-nickel-tin alloy as claimed in claim 1 with the a