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A microstructural and mechanical analysis of perforation of aluminum alloysMorgan, David Scott 05 1900 (has links)
No description available.
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Al₃(Sc₁₋x, Zrx) dispersoids in aluminum alloys : coarsening and recrystallization controlRiddle, Yancy Willard 12 1900 (has links)
No description available.
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Effect of loading condition, stress state and strain on three-dimensional damage evolution in 6061 wrought Al-alloyAgarwal, Himanshu 05 1900 (has links)
No description available.
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The effects of thermal processing on the mechanical properties of AA2024, 2014 and 2618 aluminum alloysLi, Xiao, 1963- 01 April 1993 (has links)
This study determined the independent effects of various homogenization cycles and
precipitation treatments on the elevated temperature workability and the final ambient
temperature mechanical properties of AA2024 aluminum alloy and on the T3 tensile
properties of 2014 aluminum alloy as well as T6 tensile properties of 2618 and 2618 (Curich)
aluminum alloys. The elevated-temperature tensile and extrusion tests indicate that the
workability of AA2024 alloy improves with elevated-temperature precipitation treatment as
suggested by earlier investigations. The precipitation treatments do not appear to degrade
the ambient-temperature T3 and T8 tensile properties. The time at the precipitation
temperature appears to affect the T3 and T8 tensile properties in unextruded ingot, longer
times especially providing both relatively high ambient-temperature strength and ductility of
AA2024 alloy. The time at the standard homogenization temperature and the heat-up and
cool-down rates do not dramatically affect the T3 tensile properties of unextruded ingot of
AA2024 and 2014 alloys. However, long soak times at the homogenization temperature
and more rapid cooling rates may improve the properties somewhat of AA2024 alloy and
longer heat-up times and rapid cooling rates may slightly improve the properties of 2014
alloy. The higher standard solution temperature appears to increase both strength and
ductility of 2014 alloy over lower temperatures. The homogenization temperature affects
the T6 tensile properties of 2618 and 2618 (Cu-rich) alloys, a high homogenization
temperature (compare to standard homogenization temperature) providing both high
strength and ductility. Increased manganese and copper appears to increase the strength,
but slightly decreases the ductility. The standard aging temperature and time produce
higher strength but lower the ductility than lower temperatures at the same or shorter aging
times in 2618 (Cu-rich) alloy. / Graduation date: 1993
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The fatigue and tensile properties of A356 aluminium alloy wheels in various post cast conditionsJacobs, H. 27 November 2008 (has links)
M.Ing. / This dissertation investigates the fatigue and monotonic tensile properties of cast aluminium alloy wheels in various post cast conditions. It was found that monotonic tensile properties could be used in the original universal slopes method of Manson to predict the fatigue properties as a conservative first approximation for A356 cast aluminium alloy wheels. Using finite element analysis and the predicted fatigue properties the fatigue life of A356 aluminium alloy wheels could be determined. Further work is required on the surface effect of paint on the wheel and residual stress on the surface of the wheel.
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Optimisation of the mechanical properties of a modified aluminium 7% silicon-magnesium casting alloy by heat treatment22 September 2015 (has links)
Due to the problem of obtaining the predicted mechanical properties for Al-Si alloys, especially after heat treatment, trial batches of sodium, strontium and unmodified alloys were cast. The alloys were cast using a standard test bar design. The material was solution treated, quenched and aged (at both increasing time and temperature) to obtain the best properties possible. Initial background information and theory was obtained at libraries to obtain a better working knowledge of the alloy...
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Quantitative characterization of damage evolution in an Al-Si-Mg base cast alloyDighe, Manish D. 08 1900 (has links)
No description available.
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Characterization and Mechanical Properties of Nanoscale Precipitates in Modified Al-Si-Cu Alloys Using Transmission Electron Microscopy and 3D Atom Probe Tomography.Hwang, Junyeon 05 1900 (has links)
Among the commercial aluminum alloys, aluminum 319 (Al-7wt%Si-4wt%Cu) type alloys are popularly used in automobile engine parts. These alloys have good casting characteristics and excellent mechanical properties resulting from a suitable heat treatment. To get a high strength in the 319 type alloys, grain refining, reducing the porosity, solid solution hardening, and precipitation hardening are preferred. All experimental variables such as solidification condition, composition, and heat treatment are influence on the precipitation behavior; however, precipitation hardening is the most significant because excess alloying elements from supersaturated solid solution form fine particles which act as obstacles to dislocation movement. The challenges of the 319 type alloys arise due to small size of precipitate and complex aging response caused by multi components. It is important to determine the chemical composition, crystal structure, and orientation relationship as well as precipitate morphology in order to understand the precipitation behavior and strengthening mechanism. In this study, the mechanical properties and microstructure were investigated using transmission electron microscopy and three dimensional atom probe tomography. The Mn and Mg effects on the microstructure and mechanical properties are discussed with crystallographic study on the iron intermetallic phases. The microstructural evolution and nucleation study on the precipitates in the low-Si 319 type aluminum alloys are also presented with sample preparation and analysis condition of TEM and 3DAP tomography.
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