METALS — Mechanical Properties

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Posts Tagged ‘METALS — Mechanical properties’

Effects of calcium on texture and mechanical properties of hot-extruded mg–zn–ca alloys

Abstract: The effects of calcium on microstructure, texture and mechanical properties of hot-extruded Mg–Zn–Ca alloys were studied. The results showed that calcium elements can weaken the strong basal textures and refined the grain size of extruded Mg–Zn–Ca alloys. The weakening of extrusion textures with increasing content of Ca is related to the particle stimulated nucleation of recrystallization (PSN) and the particle retarded the growth of the dynamic recrystallization grains. The increase of the tensile elongation is attributing to the weakened extrusion textures and refined grains. [Copyright &y& Elsevier]

March 1, 2012 Tags: CALCIUM alloys, EXTRUSION process, METALS -- Mechanical properties, METALS -- Texture, MICROSTRUCTURE, NUCLEATION, RECRYSTALLIZATION (Metallurgy)
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Influence of microstructure and its evolution on the mechanical behavior of modified mar-m247 fine-grain superalloys at 871°c

Abstract: This study added Re to Mar-M247 fine-grain superalloy and investigated the influence of microstructure and its evolution on the mechanical behavior at 871°C. Mar-M247 and modified Mar-M247 alloys consisted of dual precipitation of primary and secondary γ′ particles in the γ matrix. An increase in Re content led to a reduction in the primary γ′ phase with the γ′ phase becoming finer; however, the addition of Re did not have an obvious influence the secondary γ′ phase. Tensile and creep tests (871°C/379MPa) showed that both tensile and creep strength increased with an increase in Re content up to a maximum of 3wt%. In the early creep stage, the addition of Re improved creep resistance by increasing the strength of the γ matrix and decreasing the inter-particle spacing. In the later creep stage, the linear fraction of the γ′ raft in stress axial direction increased following the addition of Re, resulting in improved creep resistance. Observation of microstructure evolution indicated that only secondary γ′ phase coarsened directionally into a rafting structure and the primary γ′ phase was unaffected by creep. An interrupted creep tests verified that the γ′ rafting structure initiated in the primary creep stage and completed in the secondary creep stage. The addition of excessive quantities of Re, such as 5wt%, resulted in the formation of needle-like P phase, which damaged the tensile and creep properties. During tensile and creep tests, cracks initiated and propagated along grain boundary (GB) in alloys containing 0–3wt% Re; and propagated along both the GB and P/γ interface in an alloy containing 5wt% Re. In conclusion, optimal results were obtained for fine-grain Mar-M247 following the addition of 3wt% Re. [Copyright &y& Elsevier]

March 1, 2012 Tags: GRAIN boundaries, HEAT resistant alloys, METALS -- Creep, METALS -- Mechanical properties, MICROSTRUCTURE, PRECIPITATION (Chemistry), REDUCTION (Chemistry), STRENGTH of materials, TEMPERATURE effect
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The influence of zn additions on the microstructure and creep resistance of high pressure die cast magnesium alloy ae44

Abstract: Mg–4Al–4RE (AE44) alloys with 1wt.%, 2wt.% and 4wt.% Zn additions were produced by high pressure die casting and their mechanical properties, especially creep properties at elevated temperatures, were evaluated. Although the tensile properties appear not be affected by the additions of Zn, there is a significant decrease in creep resistance with increasing Zn addition. To understand the influence of Zn additions on creep resistance, microstructures of the alloys before and after creep testing or long-term annealing at high temperatures were examined. It is revealed that, as a result of Zn additions, there is a transition in the predominant intermetallic phase form Al–RE to Al2REZn2. The Zn additions also lead to an increased level of Zn solute supersaturated in the α-Mg matrix and, as a result, dynamic precipitation occurred during creep. Based on the microstructural observations, the adverse effect of Zn additions on creep resistance of AE44 is discussed. [Copyright &y& Elsevier]

March 1, 2012 Tags: ADDITION reactions, DIE castings, HIGH pressure (Science), MAGNESIUM alloys, METALS -- Creep, METALS -- Mechanical properties, MICROSTRUCTURE, ZINC
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Microstructures and mechanical properties of age-formed 7050 aluminum alloy

Abstract: The effects of age-forming on microstructures and mechanical properties of 7050 Al alloy were investigated in this work. The alloy was subjected to age-forming as well as stress-free ageing at 160°C for 6, 12, 18 and 24h, and its microstructures were characterized by electron backscatter diffraction (EBSD) and transmission electron microscopy (TEM). It was shown that creep might lead to grain elongation during age-forming, and the applied stress induces the coarsening of precipitates in 7050 Al alloy. The texture in the alloy was also influenced by age-forming. Consequently, the differences in microstructures result in differences in mechanical properties of age-forming versus traditional stress-free ageing. The ultimate tensile strength of age-formed samples were slightly lower than that of stress-free aged samples, while the yield strength of age-formed samples were apparently lower than that of stress-free aged samples. Specifically, the elongation of samples age-formed displays apparently decrease. [Copyright &y& Elsevier]

March 1, 2012 Tags: ALUMINUM alloys, METALS -- Mechanical properties, MICROSTRUCTURE, STRAINS & stresses, STRENGTH of materials, TEMPERATURE effect, TRANSMISSION electron microscopy
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Room and elevated temperature mechanical properties in the as-extruded mg–al–ca–mn alloys

Abstract: Fine DRXed grains are formed in conjunction with coarse unrecrystallized regions in the as-extruded Mg–4Al–3Ca–0.3Mn (mass%) alloy produced by gravity casting technology. The unrecrystallized region exhibits strong basal texture whose basal plane is parallel to the extrusion direction. Yield anisotropy is appeared in the compressive test sample measured at ambient temperature due to formation of tensile twinning in the unrecrystallized region. The obtained 0.2% proof stresses in tension and compression are 331 and 285MPa, respectively. The yield anisotropy is improved when the test temperature increases, leading to remarkable elevated temperature mechanical properties. The room and elevated temperature mechanical properties are comparable to those in WE43A Mg and T6-treated A4032 Al alloys. [Copyright &y& Elsevier]

March 1, 2012 Tags: EXTRUSION process, HIGH temperatures, MAGNESIUM alloys, METALS -- Mechanical properties, RECRYSTALLIZATION (Metallurgy), TWINNING (Crystallography)
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Investigation of plc band nucleation in aa5754

Abstract: The purpose of the present work is the experimental investigation of the nucleation of PLC deformation bands in the aluminium alloy AA5754. The PLC bands are investigated using both mechanical methods and infrared (IR) thermography. The latter employs a high-speed IR camera which captures local changes of radiated power resulting from mechanical dissipation and heating due to the nucleation of PLC bands. The resulting IR images are used to determine spatio-temporal power field variations via image subtraction. Furthermore, band trajectories obtained from the IR images are used to study possible correlations between the spatio-temporal evolution of stress and radiated power in the specimens and PLC band development. [Copyright &y& Elsevier]

March 1, 2012 Tags: ALUMINUM alloys, ENERGY bands, ENERGY dissipation, INFRARED radiation, METALS -- Mechanical properties, NUCLEATION, THERMOGRAPHY
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Effect of friction stir processing on microstructure and mechanical properties of aluminium

Abstract: Commercially pure aluminium was subjected to friction stir processing (FSP) to study the microstructure developed and its effects on the mechanical properties. Friction stir processing refined the grain size to 3μm in a single pass from the starting coarse grain size of 84μm. Electron backscattered diffraction (EBSD) results showed occurrence of dynamic recrystallization and also revealed existence of different orientations within the stir zone and across the transition zone. Transmission electron microscopy (TEM) revealed fine grains with well defined boundaries. The arrangement and absorption of dislocation into the sub-grain boundaries, formed by dynamic recovery, was also revealed by TEM. The yield strength of the material was improved by a factor of 2.4 after FSP owing to grain refinement. The most important feature of the friction stir processed material was that even after this significant improvement in strength there was little loss of ductility. The hardness also improved by 34% with the peak hardness being observed towards the advancing side. [Copyright &y& Elsevier]

March 1, 2012 Tags: ALUMINUM, ELECTRONS -- Backscattering, FRICTION stir processing, GRAIN boundaries, HARDNESS, METALS -- Mechanical properties, MICROSTRUCTURE, TRANSMISSION electron microscopy
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Investigation into microstructure and mechanical properties of nial-mo composites produced by directional solidification

Abstract: Mo fiber reinforced NiAl in situ composites with a nominal composition Ni-43.8Al-9.5Mo (at.%) were produced by specially controlled directional solidification using a laboratory-scale Bridgman furnace equipped with a liquid metal cooling (LMC) device. The microstructure of as-produced composites was characterized by electron microscopy (SEM, TEM, HRTEM) and microanalysis (EDX, SAED). The strength and plasticity at elevated temperatures (700°C, 1100°C) were examined by tensile tests. The fracture toughness at room temperature (RT) was measured by four-point bending tests. For a constant temperature gradient (8.9K/mm) it was found that the alignment and size/spacing of single crystalline Mo fibers were mainly controlled by the solidification rate. When the solidification rate decreased from 1.33mm/min to 0.33mm/min the Mo fibers arranged themselves gradually from an initially irregular distribution to an alignment parallel to the solidification direction. The strength at elevated temperatures and the fracture toughness at RT were dominated by the Mo fiber alignment: the yield strength of the composites increased from 273MPa at 700°C and 68MPa at 1100°C for a random Mo fiber arrangement to 811MPa at 700°C and 344MPa at 1100°C for well aligned Mo fibers. The fracture toughness at RT was also apparently improved from 8.7MPam0.5 to 14.5MPam0.5 upon Mo fiber alignment. The influence of Mo fiber alignment on the mechanical properties of as-produced NiAl-Mo composites will be discussed in terms of the active strengthening and toughening mechanisms. [Copyright &y& Elsevier]

March 1, 2012 Tags: DIRECTIONAL solidification, ELECTRIC furnaces, ELECTRON microscopy, METALLIC composites, METALS -- Mechanical properties, MICROSTRUCTURE, NICKEL alloys, STRENGTH of materials, TEMPERATURE effect
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Crystal plasticity approach for predicting the bauschinger effect in dual-phase steels

Abstract: A multi-scale micro-mechanical model was proposed to predict the cyclic behavior of dual-phase steels. The approach proposed in this study incorporates a simplified dislocation density model into the crystal plasticity finite element method (CP-FEM). The back stress resulting from dislocation pileups was used to reproduce the transient hardening behavior during load reversal. The simulations conducted using representative volume elements for the dual-phase steels lead to the following conclusions: (1) the large Bauschinger effect (BE) and permanent softening in dual-phase steels originate primarily from the inhomogeneity due to the soft and hard phases; (2) the elastic incompatibility due to the grain orientation distribution generates some BE, but is not sufficient to explain the measured stress–strain curve; and (3) the inclusion of the back stress produced by the dislocation pileup can explain the strain hardening stagnation during reverse loading. [Copyright &y& Elsevier]

March 1, 2012 Tags: BAUSCHINGER effect, DISLOCATIONS in metals, METALS -- Mechanical properties, PLASTICITY, PREDICTION models, STRESS-strain curves, TRANSIENTS (Dynamics)
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Effect of repeated impacts on mechanical properties and fatigue fracture morphologies of 6061-t6 aluminum subject to laser peening

Abstract: The effect of repeated impacts on mechanical properties and fatigue fracture morphologies of 6061-T6 aluminum subject to laser peening (LP) were investigated. Compared with the untreated samples, nano-hardness and fatigue lives of the samples subjected to 1-3 LP impacts increased by 18.1–59.1% and 7.3–99.4%, respectively. Residual stress presented compressive state on the superficial layer of the samples after LP, and the value increased with the increase of the impact number. LP caused the location of fatigue crack initiation (FCI) transferring from the top surface to sub-surface, and the distance from FCI to the top surface increased with the increase of the impact number. Meanwhile, the fatigue striation spacing (FSS) on the fatigue crack growth (FCG) area decreased with the increase of the impact number. In addition, the enhancement mechanism of LP on the resistance of FCI and FCG were discussed. [Copyright &y& Elsevier]

March 1, 2012 Tags: ALUMINUM alloys, ALUMINUM alloys -- Fatigue, HARDNESS, LASER peening, MATERIALS -- Compression testing, METALS -- Mechanical properties, RESIDUAL stresses, SURFACES (Technology)FRACTURE
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