Effect of SiC-reinforcement and equal-channel angular pressing on microstructure and mechanical properties of AA2017 (bibtex)
by S. Wagner, S. Siebeck, M. Hockauf, D. Nestler, H. Podlesak, B. Wielage, M.F.-X. Wagner
Abstract:
This article deals with powder metallurgical production and modification of properties of a composite material based on an age-hardenable Al–Cu alloy. The main objective is to improve the mechanical properties by particle reinforcement and equal-channel angular pressing (ECAP). Our approach makes use of four hardening mechanisms: precipitation hardening, particle reinforcement, strain-hardening, and grain boundary hardening associated with an ultrafine-grained microstructure produced by ECAP. The main processing steps are high-energy ball milling, hot-isostatic pressing, extrusion, heat treatment, and a single ECAP pass. Microstructures are analyzed by optical microscopy, scanning electron microscopy, and scanning transmission electron microscopy. The mechanical properties are characterized by hardness measurements and quasi-static tensile testing. Our experimental results show that the proposed processing route results in a nearly homogeneous distribution of SiC particles in the matrix. The combination of particle reinforcement and ECAP leads to an improvement of ultimate tensile strength by almost 300 MPa compared to the unreinforced alloy. A subsequent heat treatment leads to a further increase in hardness and strength that can be related to changes in the defect structure. Our study provides detailed information on how processing steps, microstructures, and mechanical behavior are interrelated in this technologically relevant class of materials.
Reference:
Wagner, S., Siebeck, S., Hockauf, M., Nestler, D., Podlesak, H., Wielage, B., Wagner, M.F.-X.: Effect of SiC-reinforcement and equal-channel angular pressing on microstructure and mechanical properties of AA2017, Advanced Engineering Materials 14, 388-393, 2012.
Bibtex Entry:
@Article{Wagner2012,
Title = {{Effect of {SiC}-reinforcement and equal-channel angular pressing on microstructure and mechanical properties of {AA2017}}},
Author = {Wagner, S. and Siebeck, S. and Hockauf, M. and Nestler, D. and Podlesak, H. and Wielage, B. and Wagner, M.F.-X.},
Journal = {Advanced Engineering Materials},
Year = {2012},
Number = {6},
Pages = {388--393},
Volume = {14},
Abstract = {This article deals with powder metallurgical production and modification of properties of a composite material based on an age-hardenable Al–Cu alloy. The main objective is to improve the mechanical properties by particle reinforcement and equal-channel angular pressing (ECAP). Our approach makes use of four hardening mechanisms: precipitation hardening, particle reinforcement, strain-hardening, and grain boundary hardening associated with an ultrafine-grained microstructure produced by ECAP. The main processing steps are high-energy ball milling, hot-isostatic pressing, extrusion, heat treatment, and a single ECAP pass. Microstructures are analyzed by optical microscopy, scanning electron microscopy, and scanning transmission electron microscopy. The mechanical properties are characterized by hardness measurements and quasi-static tensile testing. Our experimental results show that the proposed processing route results in a nearly homogeneous distribution of SiC particles in the matrix. The combination of particle reinforcement and ECAP leads to an improvement of ultimate tensile strength by almost 300 MPa compared to the unreinforced alloy. A subsequent heat treatment leads to a further increase in hardness and strength that can be related to changes in the defect structure. Our study provides detailed information on how processing steps, microstructures, and mechanical behavior are interrelated in this technologically relevant class of materials.},
Doi = {10.1002/adem.201100253},
ISSN = {14381656}
}Powered by bibtexbrowser