Article: Material properties of high-strength beryllium-free copper alloys Journal: International Journal of Materials and Product Technology (IJMPT) 2015 Vol.50 No.2 pp.124 - 146 Abstract: High strength copper alloys can be produced either by generating very fine grained low alloyed single phased or precipitation hardened copper alloys or by highly alloyed precipitation hardened copper alloys. The latter process requires special processing methods such as spray forming in order to achieve a sufficiently homogeneous microstructure. Systematic investigations on the aging behaviour of the highly alloyed nickel-manganese bronze CuNi20Mn20 demonstrate that fully crystalline copper alloys with hardness exceeding 500 HV can be produced. In addition to age hardening, swaging or severe plastic surface deformation can be used for additional grain refinement and strain hardening before precipitation hardening. In contrast to CuMn20Ni20, the low-alloyed precipitation hardened copper alloy CuNi3Si1Mg exhibits excellent thermal and electrical conductivity while maintaining acceptable strength after swaging and precipitation hardening. Finally, a systematic comparison between spray-formed or precipitation high strength hardened copper alloys and classical well-known materials such as steels or aluminium alloys was carried out by using material property charts (Ashby-maps) and highlighting the fields of application and unique property combinations of copper alloys. Inderscience Publishers - linking academia, business and industry through research

Title: Material properties of high-strength beryllium-free copper alloys

Authors: Igor Altenberger; Hans-Achim Kuhn; Hilmar R. Müller; Mansour Mhaede; Mozghan Gholami-Kermanshahi; Lothar Wagner

Addresses: Wieland-Werke AG, Graf-Arco-Str. 36, 89079 Ulm, Germany ' Wieland-Werke AG, Graf-Arco-Str. 36, 89079 Ulm, Germany ' Wieland-Werke AG, Graf-Arco-Str. 36, 89079 Ulm, Germany ' TU Clausthal, Institute of Applied Materials Science and Engineering, Agricolastr. 6, 38678 Clausthal-Zellerfeld, Germany ' TU Clausthal, Institute of Applied Materials Science and Engineering, Agricolastr. 6, 38678 Clausthal-Zellerfeld, Germany ' TU Clausthal, Institute of Applied Materials Science and Engineering, Agricolastr. 6, 38678 Clausthal-Zellerfeld, Germany

Abstract: High strength copper alloys can be produced either by generating very fine grained low alloyed single phased or precipitation hardened copper alloys or by highly alloyed precipitation hardened copper alloys. The latter process requires special processing methods such as spray forming in order to achieve a sufficiently homogeneous microstructure. Systematic investigations on the aging behaviour of the highly alloyed nickel-manganese bronze CuNi20Mn20 demonstrate that fully crystalline copper alloys with hardness exceeding 500 HV can be produced. In addition to age hardening, swaging or severe plastic surface deformation can be used for additional grain refinement and strain hardening before precipitation hardening. In contrast to CuMn20Ni20, the low-alloyed precipitation hardened copper alloy CuNi3Si1Mg exhibits excellent thermal and electrical conductivity while maintaining acceptable strength after swaging and precipitation hardening. Finally, a systematic comparison between spray-formed or precipitation high strength hardened copper alloys and classical well-known materials such as steels or aluminium alloys was carried out by using material property charts (Ashby-maps) and highlighting the fields of application and unique property combinations of copper alloys.

Keywords: high-strength copper alloys; materials selection; spray forming; precipitation hardening; fatigue; mechanical surface treatment; ultra fine grained materials; beryllium-free copper alloys.

DOI: 10.1504/IJMPT.2015.067820

International Journal of Materials and Product Technology, 2015 Vol.50 No.2, pp.124 - 146

Received: 23 Jan 2014
Accepted: 03 Oct 2014
Published online: 05 Mar 2015 *

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Title: Material properties of high-strength beryllium-free copper alloys

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