Abstract: A hybrid conductor comprising a core section of CCA wire strands and at least one surrounding outer layer of high strength copper alloy of at least 60 ksi and preferably 80 ksi tensile strength, at least 85% IACS conductivity and at least 6% elongation.

Abstract: A copper base alloy achieves a breakthrough electrical conductor product of strength, flexure and conductivity of minimal inverse in relationship of at least 85% IACS electrical conductivity while providing an 80 to 85 ksi tensile strength, an increase of at least 33% in strength compared to prior art and is made from an alloy containing 0.2-0.5 w/o chromium, 0.02-0.20 w/o silver and 0.04-0.16 w/o of a third metallic component selected from tin, magnesium and tin/magnesium together.

Abstract: A process is provided for forming an age hardened wire for use as an electrical conductor, which wire is formed from a copper base alloy consisting of from 1.25 to 3.6 wt % nickel, from 0.25 to 0.45 beryllium, and the balance copper and impurities which do not affect the properties of said alloy, with the nickel and beryllium being present in the copper base alloy in a ratio of nickel to beryllium from 5.0 to 8.0. The process comprises the steps of providing a copper base alloy material consisting of from 1.25 to 3.6 wt % nickel, from 0.25 to 0.45 beryllium, and the balance copper and impurities which do not affect the properties of said alloy, which nickel and beryllium are present in the copper base alloy in a ratio of nickel to beryllium from 5.0 to 8.0, cold working the material in a single step; and age hardening the cold worked material in a single step to form a wire in a cold worked and aged hardened condition having an electrical conductivity of at least about 60% IACS.

Abstract: Two copper alloys are provided. The first copper alloy may have a composition in the range of from 0.2 to 0.6 wt % chromium, from 0.005 to 0.25 wt % silver, and the balance copper. The second copper alloy may have a composition in the range of from 0.2 to 0.6 wt % chromium, from 0.01 to 0.12 wt % magnesium, and the balance copper. The copper alloys of the present invention may also include zirconium to provide additional softening resistance. These copper alloys can easily be drawn or rolled to fine and ultra fine sizes (0.010 inch and smaller) to be used as a single end wire and constructions made therefrom.

Abstract: In accordance with the present invention, a copper alloy wire having high strength and high conductivity is provided. The copper alloy wire is formed from a copper base alloy containing from 0.05 to 0.9 wt % magnesium and more than 15 ppm impurities in total. The wire has a single end diameter no greater than 0.10 inches, a tensile strength of at least 100 ksi, and an electrical conductivity greater than 60% IACS. A process for producing the copper wire of the present invention is also described.

Abstract: High strength, high conductivity copper alloy wire and a cable therefrom and method for manufacturing same, wherein the copper alloy contains chromium from 0.15-1.30%, zirconium from 0.01-0.15% and the balance essentially copper. The alloy wire is heat treated, cold worked to an intermediate gage, heat treated, cold worked to final gage, and finally heat treated.

Abstract: High strength, high conductivity copper alloy wire and a cable therefrom and method for manufacturing same, wherein the copper alloy contains chromium from 0.15-1.30%, zirconium from 0.01-0.15% and the balance essentially copper. The alloy wire is heat treated, cold worked to an intermediate gage, heat treated, cold worked to final gage, and finally heat treated. A major portion of the chromium and zirconium are present as precipitated, sub-micron sized particles in a copper matrix. In addition, the wire has a gage of 0.010 inch or less and a tensile strength of at least 55% ksi, an electrical conductivity of at least 85% IACS, and a minimum elongation of 6% in 10".

Abstract: Machinable alpha beta brass having a reduced lead concentration is claimed. The alloy contains bismuth to improve machinability. Either a portion of the zinc is replaced with aluminum, silicon or tin, or a portion of the copper is replaced with iron, nickel or manganese.

Abstract: Machinable alpha beta brass having a reduced lead concentration is claimed. The alloy contains bismuth to improve machinability. Either a portion of the zinc is replaced with aluminum, silicon or tin, or a portion of the copper is replaced with iron, nickel or manganese.

Abstract: Machinable copper alloys having a reduced lead concentration are disclosed. An additive to the alloy accumulates both at the grain boundaries and intragranularly. The additive facilitates chip fracture or lubricates the tool. One additive is a mixture of bismuth and lead with the lead concentration below about 2% by weight.