Stress-induced Damage and Post-fire Response of Aluminum Alloys

Aluminum alloys have increasing applications in construction and transportation industries. Both 5xxx-series (Al-Mg) and 6xxx-series (Al-Mg) alloys are frequently used in marine construction because of their light weight, high strength, and corrosion resistance. One of the major concerns regarding the marine application of aluminum alloys is their mechanical performance in fire scenarios. The material strength may be degraded due to both thermal and mechanical damage during fire exposure. This work emphasizes the stress-induced mechanical (physical) damage and its impact on the residual (post-fire) performance of 5083-H116 and 6061-T651 aluminum alloy. Thermomechanical tests were performed at various temperatures and stresses to study the stress-induced damage at induced plastic creep strain levels. Unstressed thermally exposed and thermomechanically damaged samples were examined to separate the stress-induced microstructural damage. The stress-induced microstructural damage primarily manifests itself as dynamic recovery at low creep temperatures, while cavitation, dynamic recrystallization and dynamic precipitation (in Al6061) are the types of damage developed in the high creep strains at high exposure temperatures. Different creep mechanisms are also studied for both Al5083 and Al6061. The post-fire mechanical response at room temperature after thermo-mechanical damage was investigated with reference to the damaged microstructure present in the material. Residual material strengths based on deformed cross sectional area after the creep test were calculated to provide insight into how microstructural damage affects the post-fire material performance. The competing effects of strength degradation caused by cavitation and strengthening due to grain elongation and subgrain refinement were investigated. Engineering residual material strengths calculated based on the original cross sectional area prior to creep tests were also studied to provide guidance for structural design.

[1]  P. Anderson,et al.  Stress redistribution and cavity nucleation near a diffusively growing grain boundary cavity , 2000 .

[2]  G. A. Edwards,et al.  The precipitation sequence in Al–Mg–Si alloys , 1998 .

[3]  J. C. Huang,et al.  Deformation mechanisms during low-and high-temperature superplasticity in 5083 Al-Mg alloy , 2002 .

[4]  E. Evangelista,et al.  Influence of severe plastic deformations on secondary phase precipitation in a 6082 Al-Mg-Si alloy , 2005 .

[5]  D. Dunand,et al.  Monkman-grant analysis of creep fracture in dispersion-strengthened and particulate-reinforced aluminum , 1999 .

[6]  M. E. Kassner,et al.  Creep cavitation in metals , 2003 .

[7]  J. Hancock Creep cavitation without a vacancy flux , 1976 .

[8]  H. Evans Mechanisms of creep fracture , 1984 .

[9]  R. Völkl,et al.  Mechanical testing of ultra-high temperature alloys , 2004 .

[10]  Jean Lemaitre,et al.  Application of Damage Concepts to Predict Creep-Fatigue Failures , 1979 .

[11]  M. Yoo,et al.  Nucleation under time-dependent supersaturation , 1987 .

[12]  M. Starink,et al.  β′ and β precipitation in an Al–Mg alloy studied by DSC and TEM , 1998 .

[13]  Jun Chen,et al.  New approach for modeling flow stress of aluminum alloy 6A10 considering temperature variation , 2010 .

[14]  D. Scott MacKenzie,et al.  Physical metallurgy and processes , 2003 .

[15]  D. Hull,et al.  The growth of grain-boundary voids under stress , 1959 .

[16]  Michael F. Ashby,et al.  Intergranular fracture during power-law creep , 1979 .

[17]  C. Hamilton,et al.  Inhomogeneities in initial cavity distribution in a superplastic Al 5083 alloy , 1997 .

[18]  D. Hayhurst CDM Mechanisms-Based Modelling of Tertiary Creep: Ability to Predict the Life of Engineering Components , 2005 .

[19]  Michael F. Ashby,et al.  Intergranular fracture at elevated temperature , 1975 .

[20]  J. Greenwood,et al.  Intergranular cavitation in stressed metals , 1954 .

[21]  E. Evangelista,et al.  Substructures in aluminium from dynamic and static recovery , 1988 .

[22]  Tsutomu Tanaka,et al.  Cavitation Behavior in Superplastically Deformed Zn-22 mass%Al Alloy at Room Temperature , 2004 .

[23]  E. E. Underwood,et al.  Dynamic recovery in aluminum , 1971 .

[24]  K. T. Ramesh,et al.  Strengthening mechanisms in an Al–Mg alloy , 2010 .

[25]  V. Sundararaghavan,et al.  A probabilistic crystal plasticity model for modeling grain shape effects based on slip geometry , 2012 .

[26]  M. F. Ashby,et al.  Creep fracture by coupled power-law creep and diffusion under multiaxial stress , 1982 .

[27]  X. Yan,et al.  Microstructure evolution of 7050 aluminum alloy during hot deformation , 2010 .

[28]  Johannes May,et al.  Mechanical Properties, Dislocation Density and Grain Structure of Ultrafine-Grained Aluminum and Aluminum-Magnesium Alloys , 2007 .

[29]  D. Matlock,et al.  A model for creep fracture based on the plastic growth of cavities at the tips of grain boundary wedge cracks , 1977 .

[30]  S. Agarwal,et al.  Dynamic Recrystallization of AA5083 at 450 °C: the Effects of Strain Rate and Particle Size , 2008 .

[31]  P. Houtte,et al.  A new way to include the grain shape in texture simulations with the Taylor model , 1985 .

[32]  Quan Guo-zheng,et al.  Characterization for Dynamic Recrystallization Kinetics Based on Stress-Strain Curves , 2013 .

[33]  J. Rice,et al.  The shape of intergranular creep cracks gro′ing by surface diffusion , 1973 .

[34]  Trevor A. Dean,et al.  A Review on Damage Mechanisms, Models and Calibration Methods under Various Deformation Conditions , 2005 .

[35]  F. A. McClintock,et al.  A Criterion for Ductile Fracture by the Growth of Holes , 1968 .

[36]  E. Evangelista,et al.  Serrated grain boundaries in hot-worked aluminum alloys at high strains , 1995 .

[37]  G. Subhash,et al.  Two new expanding cavity models for indentation deformations of elastic strain-hardening materials , 2006 .

[39]  G. Odemer,et al.  Creep and Creep-Fatigue Crack Growth in Aluminium Alloys , 2011 .

[40]  D. Tabor Hardness of Metals , 1937, Nature.

[42]  Andrei Kotousov,et al.  Induction heating apparatus for high temperature testing of thermo-mechanical properties , 2009 .

[43]  B. Dyson Constraints on diffusional cavity growth rates , 1976 .

[44]  Ryan Douglas Matulich,et al.  Post-fire Mechanical Properties of Aluminum Alloys and Aluminum Welds , 2011 .

[45]  E. Romhanji,et al.  Characterization of microstructural changes in an Al-6.8 wt.% Mg alloy by electrical resistivity measurements , 2008 .

[46]  Kai Li,et al.  A fast digital image correlation method for deformation measurement , 2011 .

[47]  D. M. Tracey,et al.  On the ductile enlargement of voids in triaxial stress fields , 1969 .

[48]  C. W. Chen,et al.  On a mechanism of high temperature intercrystalline cracking , 1957 .

[49]  Ying-hong Peng,et al.  Dynamic recrystallisation and dynamic precipitation in AA6061 aluminium alloy during hot deformation , 2014 .

[50]  Shreyes N. Melkote,et al.  A unified internal state variable material model for inelastic deformation and microstructure evolution in SS304 , 2014 .

[51]  Hermann Riedel,et al.  Fracture at high temperatures , 1987 .

[52]  W. Wen,et al.  An investigation of serrated yielding in 5000 series aluminum alloys , 2003 .

[53]  E. Hall,et al.  The Deformation and Ageing of Mild Steel: III Discussion of Results , 1951 .

[54]  T. Langdon,et al.  The inter-relationship between grain boundary sliding and cavitation during creep of polycrystalline copper , 1996 .

[55]  J. Maljaars,et al.  Fire exposed aluminium structures , 2005 .

[56]  B. Lattimer,et al.  Residual mechanical properties of aluminum alloys AA5083-H116 and AA6061-T651 after fire , 2014 .

[57]  H. Liao,et al.  Dynamic precipitation of Mg2Si induced by temperature and strain during hot extrusion and its impact on microstructure and mechanical properties of near eutectic Al–Si–Mg–V alloy , 2014 .

[58]  Thomas Pardoen,et al.  Microstructure, local and global mechanical properties of friction stir welds in aluminium alloy 6005A-T6 , 2008 .

[59]  J. Tullis,et al.  Compositional changes of minerals associated with dynamic recrystallizatin , 1991 .

[60]  Knut Marthinsen,et al.  Modeling recrystallization kinetics, grain sizes, and textures during multipass hot rolling , 1996 .

[61]  W. Nix Mechanisms and controlling factors in creep fracture , 1988 .

[62]  Zhengdong Wang,et al.  A review of creep analysis and design under multi-axial stress states , 2007 .

[63]  R. Raj,et al.  Intergranular fracture in bicrystals—II , 1982 .

[64]  John W. Hutchinson,et al.  Void Growth and Collapse in Viscous Solids , 1982 .

[65]  W. Nix,et al.  The coalescence of large grain boundary cavities in silver during tension creep , 1978 .

[66]  M. Yoo,et al.  Interaction of slip with grain boundary and its role in cavity nucleation , 1986 .

[67]  M. F. Ashby,et al.  Intergranular fracture during power-law creep under multiaxial stresses , 1980 .

[68]  J. Cahoon,et al.  The determination of yield strength from hardness measurements , 1971, Metallurgical Transactions.

[69]  T. Nieh,et al.  Superplastic behavior of an Al/Mg alloy at elevated temperatures , 2003 .

[70]  I-Wei Chen,et al.  Mechanisms of cavity growth in creep , 1983 .

[71]  L. Svensson,et al.  Growth mechanism of intergranular creep cavities in α-brass , 1982 .

[72]  J. C. Werenskiold,et al.  Dynamic precipitation during severe plastic deformation of an Al–Mg–Si aluminium alloy , 2008 .

[73]  R. Raj Intergranular fracture in bicrystals , 1978 .

[74]  H. Riedel Cavity nucleation at particles on sliding grain boundaries. A shear crack model for grain boundary sliding in creeping polycrystals , 1984 .

[75]  Jie Zhou,et al.  A characterization for the dynamic recrystallization kinetics of as-extruded 7075 aluminum alloy based on true stress–strain curves , 2012 .

[76]  D. R. Hayhurst,et al.  Creep rupture of structures , 1974, Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences.