Nanocrystalline Metal Enabled Conductors for Enhanced Strength-to-weight Aerospace Electrical Wiring

Winfield, Ian

28 July 2010

High strength-to-weight nanocrystalline alloy enabled conductor (NEC) prototypes were successfully developed by reinforcing an oxygen-free copper core material with electrodeposited cobalt phosphorus (CoP) coatings. A rule of mixtures approach was utilized to design the NEC prototypes to meet materials performance indices. Three unique NEC prototypes were produced with CoP coatings composed of alternating nanocrystalline (11 nm) and coarse-grained layers. The tensile properties were dependant on the coating microstructures, with tensile strengths of 1000 MPa, 970 MPa, and 900 MPa, respectively, and corresponding tensile elongations of 4.6%, 6.1%, and 10%, respectively. The electrical conductivity of the NEC prototypes was ~58 %IACS (resistivity of ~2.96 µΩ-cm). The rule of mixtures approach effectively predicted the tensile strength and conductivity. The NEC samples were significantly stronger than the incumbent high-strength aerospace conductor material, Be-Cu alloy CS95, which exhibits a tensile strength of only 655 MPa and conductivity of 63 %IACS.

Nanocrystalline

Strength-to-Weight

Aerospace

Conductors

Electrodeposition

Composite

Wire

0794

0538

0544

Nanocrystalline Metal Enabled Conductors for Enhanced Strength-to-weight Aerospace Electrical Wiring

Winfield, Ian

28 July 2010

High strength-to-weight nanocrystalline alloy enabled conductor (NEC) prototypes were successfully developed by reinforcing an oxygen-free copper core material with electrodeposited cobalt phosphorus (CoP) coatings. A rule of mixtures approach was utilized to design the NEC prototypes to meet materials performance indices. Three unique NEC prototypes were produced with CoP coatings composed of alternating nanocrystalline (11 nm) and coarse-grained layers. The tensile properties were dependant on the coating microstructures, with tensile strengths of 1000 MPa, 970 MPa, and 900 MPa, respectively, and corresponding tensile elongations of 4.6%, 6.1%, and 10%, respectively. The electrical conductivity of the NEC prototypes was ~58 %IACS (resistivity of ~2.96 µΩ-cm). The rule of mixtures approach effectively predicted the tensile strength and conductivity. The NEC samples were significantly stronger than the incumbent high-strength aerospace conductor material, Be-Cu alloy CS95, which exhibits a tensile strength of only 655 MPa and conductivity of 63 %IACS.

Nanocrystalline

Strength-to-Weight

Aerospace

Conductors

Electrodeposition

Composite

Wire

0794

0538

0544

The Influence of Ball Milling Time on Solid Solubility, Grain Size and Hardness of Al-V Alloys

Witharamage, Chathuranga Sandamal

25 August 2020

No description available.

Metallurgy

Materials Science

Strength-to-weight ratio

high energy ball milling

supersaturated solid solution

grain refinement