Relevant bibliographies by topics / Aluminum alloys – Mechanical properties

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  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers
  6. Reports

Academic literature on the topic 'Aluminum alloys – Mechanical properties'

Author: Grafiati
Published: 4 June 2021
Last updated: 7 February 2022

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Journal articles on the topic "Aluminum alloys – Mechanical properties"

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Zhou, Jia, Jun Ping Zhang, and Ming Tu Ma. "Study on the Formability of Aluminium Alloy Sheets at Room and Elevated Temperatures." Materials Science Forum 877 (November 2016): 393–99. http://dx.doi.org/10.4028/www.scientific.net/msf.877.393.

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This paper presents the main achievements of a research project aimed at investigating the applicability of the hot stamping technology to non heat treatable aluminium alloys of the 5052 H32 and heat treatable aluminium alloys of the 6016 T4P after six months natural aging. The formability and mechanical properties of 5052 H32 and 6016 T4P aluminum alloy sheets after six months natural aging under different temperature conditions were studied, the processing characteristics and potential of the two aluminium alloy at room and elevated temperature were investigated. The results indicated that the 6016 aluminum alloy sheet exhibit better mechanical properties at room temperature. 5052 H32 aluminum alloy sheet shows better formability at elevated temperature, and it has higher potential to increase formability by raising the temperature.
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Kucharčík, L., M. Brůna, and A. Sládek. "Influence of Chemical Composition on Porosity in Aluminium Alloys." Archives of Foundry Engineering 14, no. 2 (June 1, 2014): 5–8. http://dx.doi.org/10.2478/afe-2014-0026.

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Abstract Porosity is one of the major defects in aluminum castings, which results is a decrease of a mechanical properties. Porosity in aluminum alloys is caused by solidification shrinkage and gas segregation. The final amount of porosity in aluminium castings is mostly influenced by several factors, as amount of hydrogen in molten aluminium alloy, cooling rate, melt temperature, mold material, or solidification interval. This article deals with effect of chemical composition on porosity in Al-Si aluminum alloys. For experiment was used Pure aluminum and four alloys: AlSi6Cu4, AlSi7Mg0, 3, AlSi9Cu1, AlSi10MgCu1.
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Last, H. R., and R. K. Garrett. "Mechanical behavior and properties of mechanically alloyed aluminum alloys." Metallurgical and Materials Transactions A 27, no. 3 (March 1996): 737–45. http://dx.doi.org/10.1007/bf02648961.

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Hernández-Méndez, F., A. Altamirano-Torres, José G. Miranda-Hernández, Eduardo Térres-Rojas, and Enrique Rocha-Rangel. "Effect of Nickel Addition on Microstructure and Mechanical Properties of Aluminum-Based Alloys." Materials Science Forum 691 (June 2011): 10–14. http://dx.doi.org/10.4028/www.scientific.net/msf.691.10.

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In this work a comparative study between microstructure and mechanical properties of aluminum-nickel alloys with different contents of nickel was carried out. Alloys were produced by powders metallurgy. Characterization results indicates that the microstructure of the aluminum-nickel alloys present a thin and homogeneous distribution of an intermetallic compound in the aluminum’s matrix, identified as Al3Ni. Furthermore, it was find out that the amount of intermetallic Al3Ni increase as the nickel content in the alloy rises. Regarding the mechanical properties evaluated; it was establishes that the hardness, compression and flexion resistances also were improved due to the presence of the intermetallic compound.
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Zhao, Xuehang, Haifeng Li, Tong Chen, Bao’an Cao, and Xia Li. "Mechanical Properties of Aluminum Alloys under Low-Cycle Fatigue Loading." Materials 12, no. 13 (June 27, 2019): 2064. http://dx.doi.org/10.3390/ma12132064.

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In this paper, the mechanical properties of 36 aluminum alloy specimens subjected to repeated tensile loading were tested. The failure characteristics, stress-strain hysteresis curves and its corresponding skeleton curves, stress cycle characteristics, and hysteretic energy of specimens were analyzed in detail. Furthermore, the finite element model of aluminum alloy specimens under low-cycle fatigue loading was established and compared with the experimental results. The effects of specimen parallel length, parallel diameter, and repeated loading patterns on the mechanical properties of aluminum alloys were discussed. The results show that when the specimen is monotonously stretched to fracture, the failure result from shearing break. When the specimen is repeatedly stretched to failure, the fracture of the specimen is a result of the combined action of tensile stress and plastic fatigue damage. The AA6061, AA7075, and AA6063 aluminum alloys all show cyclic softening characteristics under repeated loading. When the initial stress amplitude of repeated loading is greater than 2.5%, the repeated tensile loading has a detrimental effect on the deformability of the aluminum alloy. Finally, based on experiment research as well as the results of the numerical analysis, the calculation method for the tensile strength of aluminum alloys under low-cycle fatigue loading was proposed.
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Mamala, A., and W. Sciężor. "Evaluation of the Effect of Selected Alloying Elements on the Mechanical and Electrical Aluminium Properties." Archives of Metallurgy and Materials 59, no. 1 (March 1, 2014): 413–17. http://dx.doi.org/10.2478/amm-2014-0069.

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Abstract Modern industry expects aluminum products with new, unusual, and well-defined functional properties. Last years we are able to notice constant development of aluminium alloys. In food industry, power engineering, electrical engineering and building engineering, flat rolled products of 1XXX series aluminium alloys are used.8XXX series alloys registered in Aluminium Association during last 20 years may be used as an alternative. These alloys have very good thermal and electrical conductivity and perfect technological formability. Moreover, these materials are able to obtain by aluminium scrap recycling. Fundamental alloy additives of 8XXX series are Fe, Si, Mn, Mg, Cu and Zn. Aluminium alloying with these additives makes it possible to obtain materials with different mechanical ale electrical properties. In this paper, the analysis of alloy elements content (in 8XXX series) effect on chosen properties of material in as cast and after thermal treatment tempers has been presented.
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Araújo Filho, Oscar Olimpio, Alexandre Douglas Araújo de Moura, Everthon Rodrigues de Araújo, Maurílio José dos Santos, Cezar Henrique Gonzalez, and Flávio José da Silva. "Manufacturing and Characterization of AA1100 Aluminum Alloy Metal Matrix Composites Reinforced by Silicon Carbide and Alumina Processed by Powder Metallurgy." Materials Science Forum 869 (August 2016): 447–51. http://dx.doi.org/10.4028/www.scientific.net/msf.869.447.

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Powder Metallurgy (PM) Techniques consists in a suitable technique to process composites materials. A specific PM technique of mechanical alloying developed to produce new materials in the solid state is a consolidated route to obtain aluminum alloys metal matrix composites. Aluminum alloys metal matrix composites allies the good properties of aluminum and its alloys but with poor mechanical properties and the reinforcement of ceramics phases which add better mechanical properties to these alloys. The research of this materials processing by PM techniques presented new materials with improved properties. In this work an AA1100 aluminum alloy was reinforced by particulate silicon carbide and alumina types of ceramic phases. The powders were mixed and then processed by mechanical alloying in a SPEX vibratory type mill. Then the powders obtained were compacted and vacuum sintered. The sintered composites were characterized by means of Scanning Electron Microscopy (SEM) plus Energy Dispersive Spectroscopy (EDS) and Vickers hardness (HV) tests to evaluate the mechanical behavior.
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Bezerra, Carlos Augusto, Alexandre Douglas Araújo de Moura, Edval Gonçalves de Araújo, Maurílio José dos Santos, and Oscar Olimpio de Araújo Filho. "Features of the Processing of AA2124 Aluminum Alloy Metal Matrix Composites Reinforced by Silicon Nitride Prepared by Powder Metallurgy Techniques." Materials Science Forum 802 (December 2014): 108–13. http://dx.doi.org/10.4028/www.scientific.net/msf.802.108.

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Powder Metallurgy (PM) Techniques consists in a suitable technique to process composites materials. A specific PM technique of mechanical alloying developed to produce new materials in the solid state is a well known route to obtain aluminum alloys metal matrix composites. Aluminum alloys metal matrix composites allies the good properties of aluminum and its alloys but with poor mechanical properties and the reinforcement of ceramics phases which add better mechanical properties to these alloys. The research of this materials processing by PM techniques presented new materials with improved properties. In this work an AA2124 aluminum alloy was reforced by particulated silicon nitride a kind of ceramic phase. The powders were mixed and then processed by mechanical alloying in a SPEX vibratory type mill. Then the powders obtained were compacted and vacuum sintered. The sintered composites were characterized by means of Scanning Electron Microscopy (SEM) plus Energy Dispersive Spectroscopy (EDS) and Vickers hardness tests to evaluate the mechanical behavior.
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Shen, Hua, He Liang, Wei Dong Yang, Guang Chun Yao, and Chuan Sheng Wang. "Effect of Y on Microstructure and Mechanical Properties of Aluminium Alloy." Applied Mechanics and Materials 421 (September 2013): 250–54. http://dx.doi.org/10.4028/www.scientific.net/amm.421.250.

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The effects of yttrium (Y) on microstructures and mechanical properties of aluminium alloy were investigated in detail by scanning electronic microscope (SEM), energy dispersive spectrum (EDS),X-ray diffraction and tensile test. The results show that the trend of alloys tensile strength and elongation with increasing of the Y content is a broken line. When the Y content is increased up to 0.30%, the tensile strength and elongation are 105MPa and 10.50% respectively, meanwhile, the fractograph exhibited typical ductile dimple fracture pattern. Then the alloy performance is best. The high strength of aluminum alloy is attributed to the size of Al2Y phase. Addition of Y above 0.30% in aluminum alloy may generate more the coarse Al2Y particle. It can induce the decrease in the material performance.
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Fan, Yang Yang, and Makhlouf M. Makhlouf. "Castable Aluminium Alloys for High Temperature Applications." Materials Science Forum 765 (July 2013): 8–12. http://dx.doi.org/10.4028/www.scientific.net/msf.765.8.

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Most traditional aluminium casting alloys are based on the aluminium-silicon eutectic system because of its excellent casting characteristics. However, the solidus in this system does not exceed 577 °C and the major alloying elements used with silicon in these alloys have high diffusivity in aluminium. Therefore, while these elements enhance the room temperature strength of the alloy, they are not useful at elevated temperatures. Considering nickel-base superalloys, whose mechanical properties are retained up to temperatures that approach 75% of their melting point, it is conceivable that castable aluminium alloys can be developed on the same basis so that they are useful at temperatures approaching 300 °C. In this publication, we present the thought process behind developing a new castable aluminum alloy that is designed specifically for such high temperature applications and we present the alloy’s measured castability characteristics and its elevated temperature tensile properties.
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Dissertations / Theses on the topic "Aluminum alloys – Mechanical properties"

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Matulich, Ryan Douglas. "Post-fire Mechanical Properties of Aluminum Alloys and Aluminum Welds." Thesis, Virginia Tech, 2011. http://hdl.handle.net/10919/32727.

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The focus of this research was to quantify the post-fire mechanical properties of 5083-H116 and 6082-T6 aluminum alloys. Post-fire exposure is considered heating the material to a particular temperature then cooling the material back to room temperature. The research included evaluating parent materials as well as welded samples. Post-fire mechanical properties of parent materials were evaluated at temperatures ranging from ambient to 500oC with isothermal and transient heating. Changes in material properties were evaluated through static tensile tests and hardness testing on cooled samples. Using this data, an assessment was performed to investigate the relationship between hardness and mechanical properties. For the alloys evaluated, empirical relationships were found between Vickers hardness and post-fire strength. Testing was also performed on butt welded samples of 6082-T6 exposed isothermally to temperatures ranging from ambient to 500oC. Vickers hardness profiles were measured across a sample to quantify the hardness of the weld, heat affected zone, and parent material. This was performed at room temperature and following different heat exposures. Static tensile tests were used to evaluate the effect of reheating on the welded samples. Post-fire strength of welded samples was strongly affected by weld geometry. Parent material hardness varied with reheating while weld hardness remained constant. At select temperatures, this resulted in the weld having a higher Vickers hardness than the parent material. Despite this tensile failure always occurred within the weld.
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Sun, Ning. "Friction stir processing of aluminum alloys." Worcester, Mass. : Worcester Polytechnic Institute, 2009. http://www.wpi.edu/Pubs/ETD/Available/etd-050109-144331/.

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Eaton, James Allen. "Effect of temperature and percent cold work on the mechanical properties of aluminum alloy 3104." Master's thesis, This resource online, 1992. http://scholar.lib.vt.edu/theses/available/etd-03302010-020243/.

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Morgan, David Scott. "A microstructural and mechanical analysis of perforation of aluminum alloys." Thesis, Georgia Institute of Technology, 1992. http://hdl.handle.net/1853/16361.

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Paray, Florence. "Heat treatment and mechanical properties of aluminum-silicon modified alloys." Thesis, McGill University, 1992. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=41146.

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The commercial applications of cast Al-Si alloys depend to an important extent on controlling the morphology of the eutectic silicon through thermal modification in the solid state and/or chemical modification of the melt before the production of the casting. The effects of modification and/or heat treatment on the microstructure and the mechanical properties of 356 alloy have been investigated on both permanent mold and sand cast samples. Strontium (0.02%) and sodium (0.01%) were used to produce well modified microstructures. The importance of the amount of modifier used was also examined in producing castings with 0.002% Sr and 0.08% Sr. Production parameters such as solution heat treatment time and artificial aging time were examined.
Microstructural assessment was done by quantitative metallography using image analysis coupled to SEM while mechanical testing comprised tensile testing, hardness and microhardness measurements as well as impact tests.
The greatest improvement in mechanical properties obtained with modification was observed for the lower rates of solidification, i.e sand casting. The effect of modification on the heat treatment response of 356 alloy was investigated. The differences between unmodified and modified microstructures were more important in sand cast samples than in permanent mold cast samples. After one hour of solution heat treatment at 540$ sp circ$C, both permanent mold unmodified and modified microstructures became similar in terms of silicon particle size and sphericity. The processes which led to this were different. Silicon platelets in the unmodified structures segmented while silicon particles in the modified alloy coarsened. The final result was however the same. In sand cast alloy, the initial microstructural differences persisted after up to 12 hours of solution treatment. The coarser the initial as-cast microstructure, the greater the improvements associated with modification and heat treatment.
It was also found that porosity caused by modification can negate many of the microstructural benefits by decreasing tensile strength and percent elongation. It was demonstrated that modification also has an influence on the aluminum matrix. The hardness of modified alloy was found to be less after the T6 temper than in unmodified alloy. This was reflected in a lower yield strength of modified 356 alloy.
Quantitative microstructure-mechanical property relationships were established for the permanent mold samples. The best silicon-structure characteristics to predict the tensile properties were found to be the particle count per unit area and the particle area.
It was also determined that hardness can be a simple and inexpensive means whereby ultimate tensile strength and yield strength of 356 alloy in the T4 condition or T6 condition can be estimated.
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Dighe, Manish D. "Quantitative characterization of damage evolution in an Al-Si-Mg base cast alloy." Thesis, Georgia Institute of Technology, 1998. http://hdl.handle.net/1853/20219.

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Sun, Ning. "Friction Stir Processing of Aluminum Alloys." Digital WPI, 2012. https://digitalcommons.wpi.edu/etd-dissertations/552.

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Friction stir processing (FSP) has been developed based on the basic principles of friction stir welding (FSW), a solid-state joining process originally developed for aluminum alloys. What is attractive about FSP is that it can be incorporated in the overall manufacturing cycle as a post-processing step during the machining operation to provide localized modification and control of microstructures in near-surface layers of metallic components. FSP has emerged as an important post-processing technique, and has been identified as a process that may have a high impact, and perhaps is a disruptive manufacturing process. In this study, FSP has been applied to Al cast alloy A206, which is a high strength, widely used cast alloy in the manufacturing industry. Motivations behind this work are to (1) investigate the feasibility of FSP on manipulating the cast microstructure and strengthening the material, and (2) to explore the viability of FSP to produce a localized particle reinforced zone in cast A206 aluminum components. The thesis will show that we have optimized FSP for processing of Al alloys to locally manipulate the cast microstructure, eliminate casting defects, and attain grain refinement and second phase homogenization. We have established the mechanism leading to the microstructure evolution and have evaluated the resultant mechanical properties, i.e. hardness, tensile property and fatigue properties. We have also synthesized a localized composite material in the A206 work piece with three different reinforcement materials via FSP. These results will be presented and discussed.
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Fuller, Christian B. "Temporal evolution of the microstructures of Al(Sc, Zr) alloys and their influence on mechanical properties." Full text available, 2003. http://images.lib.monash.edu.au/ts/theses/fuller.pdf.

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Bond, Trevor. "Microstructure and Mechanical Properties of Cold Sprayed Aluminum and Titanium Alloys." Digital WPI, 2019. https://digitalcommons.wpi.edu/etd-theses/1336.

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A combination of experimental and computational methods is used to explore the microstructure and mechanical behavior of cold sprayed 6061 aluminum alloy and Ti-6Al-4V alloy and their substrate materials. A variety of microscopic methods are used for characterization of the microstructure. The indentation size effect and characteristic length of strain gradient plasticity for the substrate materials are determined. An FEA simulation describes the behavior of a worn Berkovich nanoindenter. Stress strain is studied experimentally in the substrate materials for future comparison with bulk cold-sprayed materials. Abaqus FEA models are used to simulate a single particle impact for a particle with an oxide layer using a linear Johnson-Cook plasticity model and a bilinear Johnson-Cook plasticity model. The implications of the results are discussed for cold spray processes.
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Nittala, Aditya Kameshwara. "Electrical and Mechanical Performance of Aluminum Alloys with Graphite Nanoparticles." Ohio University / OhioLINK, 2019. http://rave.ohiolink.edu/etdc/view?acc_num=ohiou1554117521295178.

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Books on the topic "Aluminum alloys – Mechanical properties"

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International, ASM, and ebrary Inc, eds. Parametric analyses of high-temperature data for aluminum alloys. Materials Park, Ohio: ASM International, 2008.

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Fracture resistance of aluminum alloys: Notch toughness, tear resistance, and fracture toughness. Washington, D.C: Aluminum Association, 2001.

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Qld.) International Conference on Aluminium Alloys (9th 2004 Brisbane. Aluminium alloys: Their physical and mechanical properties : proceedings of the 9th International Conference on aluminium alloys (ICAA9). North Melbourne, Vic: Institute of Materials Engineering Australasia, 2004.

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Kaufman, J. G. Properties of aluminum alloys: Fatigue data and the effects of temperature, product form, and processing. Materials Park, Ohio: ASM International, 2008.

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Properties of aluminum alloys: Fatigue data and the effects of temperature, product form, and processing. Materials Park, Ohio: ASM International, 2008.

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Grzegorzewicz, Tadeusz. Bezniklowe brązy aluminiowe o podwyższonej wytrzymałości i odporności na korozję. Wrocław: Oficyna Wydawnicza Politechniki Wrocławskiej, 2005.

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Angermann, Kay. Beitrag zur Entwicklung und Fertigung einer lokalen und beanspruchungsgerechten Verstärkung für hochfeste Aluminiumbauteile. Chemnitz: TU Chemnitz, Fakultät für Maschinenbau, Institut für Werkstoffwissenschaft und Werkstofftechnik, 2011.

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Woodyard, Jack R. Machining of Fe3Al intermetallics. Washington, D.C: U.S. Dept. of the Interior, Bureau of Mines, 1992.

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International Conference on Aluminum Alloys (7th 2000 Charlottesville, Va.). Aluminium alloys: Their physical and mechanical properties : proceedings of the 7th International Conference ICAA7, held in Charlottesville, Virginia, April 9-14, 2000. Edited by Starke E. A, Sanders T. H, and Cassada W. A. Uetikon-Zuerich, Switzerland: Trans Tech Publications, 2000.

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International Conference on Aluminum Alloys (8th 2002 Cambridge, England). Aluminium alloys 2002: Their physical and mechanical properties : proceedings of the 8th International Conference ICAA8, Cambridge, UK, 2-5 July 2002. Uetikon-Zuerich, Switzerland: Trans Tech Publications, 2002.

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Book chapters on the topic "Aluminum alloys – Mechanical properties"

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Dumont, D., A. Deschamps, Yves Bréchet, and C. Sigli. "Mechanical Properties/Microstructure Relationships in Aerospace Aluminum Alloys." In Microstructures, Mechanical Properties and Processes - Computer Simulation and Modelling, 269–75. Weinheim, FRG: Wiley-VCH Verlag GmbH & Co. KGaA, 2005. http://dx.doi.org/10.1002/3527606157.ch43.

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Elgallad, E. M., A. Hekmat-Ardakan, F. Ajersch, and X.-G. Chen. "Microstructure and Mechanical Properties of AA2195 DC Cast Ingot Plates." In ICAA13: 13th International Conference on Aluminum Alloys, 1864–71. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2012. http://dx.doi.org/10.1002/9781118495292.ch279.

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Kahl, Sören, Jozefa Zajac, and Hans-Erik Ekström. "Mechanical Properties of Heat Exchanger Tube Materials at Elevated Temperatures." In ICAA13: 13th International Conference on Aluminum Alloys, 499–504. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2012. http://dx.doi.org/10.1002/9781118495292.ch72.

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Karnesky, Richard A., Nancy Y. C. Yang, Chris San Marchi, Troy D. Topping, Zhiui Zhang, Ying Li, and Enrique J. Lavernia. "Solute Distribution and Mechanical Properties of Ultra-Fine-Grained Al-Mg Alloys." In ICAA13: 13th International Conference on Aluminum Alloys, 1033–38. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2012. http://dx.doi.org/10.1002/9781118495292.ch154.

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Nyirenda, Kawunga, Chen Zejun, Chen Quanzhong, and Liu Qing. "Mechanical Properties of Multilayer 1100/7075 Aluminum Sheet Produced by Hot ARB." In ICAA13: 13th International Conference on Aluminum Alloys, 1753–60. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2012. http://dx.doi.org/10.1002/9781118495292.ch262.

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Zhemchuzhnikova, Darya, Anna Mogucheva, and Rustam Kaibyshev. "Mechanical Properties of Al-Mg-Sc-Zr Alloys at Cryogenic and Ambient Temperatures." In ICAA13: 13th International Conference on Aluminum Alloys, 879–84. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2012. http://dx.doi.org/10.1002/9781118495292.ch131.

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Biradar, N. S., and R. Raman. "Tailored Welding Technique for High Strength Al-Cu Alloy for Higher Mechanical Properties." In ICAA13: 13th International Conference on Aluminum Alloys, 945–50. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2012. http://dx.doi.org/10.1002/9781118495292.ch142.

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Dubyna, Andrii, Anna Mogucheva, and Rustam Kaibyshev. "Effect of Extensive Rolling on Mechanical Properties of an A-Mg-Sc Alloy." In ICAA13: 13th International Conference on Aluminum Alloys, 1891–96. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2012. http://dx.doi.org/10.1002/9781118495292.ch282.

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Kato, Hideomi, Shoichi Hirosawa, Kenji Matsuda, and Gary J. Shiflet. "Microstructural Change and Mechanical Properties with Isochronal Aging in Al-Ni-Gd Metallic Glasses." In ICAA13: 13th International Conference on Aluminum Alloys, 1235–40. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2012. http://dx.doi.org/10.1002/9781118495292.ch186.

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Kato, Yoshikazu, Koji Hisayuki, Masashi Sakaguchi, and Kenji Higashi. "Effect of Alloy Elements on Microstructures and Mechanical Properties in Al-Mg-Si Alloy." In ICAA13: 13th International Conference on Aluminum Alloys, 1521–26. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2012. http://dx.doi.org/10.1002/9781118495292.ch229.

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Conference papers on the topic "Aluminum alloys – Mechanical properties"

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Douglass, D. M., and J. Mazumder. "Mechanical properties of laser welded aluminum alloys." In ICALEO® ‘96: Proceedings of the Lasers and Electro-Optics for Automotive Manufacturing Conference. Laser Institute of America, 1996. http://dx.doi.org/10.2351/1.5059103.

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Shor, Alexander. "Dynamic mechanical properties of aluminum alloys GIGAS." In Shock compression of condensed matter. AIP, 2000. http://dx.doi.org/10.1063/1.1303523.

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Summers, P. T., R. D. Matulich, Scott W. Case, and Brian Lattimer. "Post-Fire Mechanical Properties and Hardness of 5083 and 6082 Aluminum Alloys." In ASME 2012 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2012. http://dx.doi.org/10.1115/imece2012-88175.

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Aluminum alloys are being increasingly used in lightweight transportation applications such as naval vessels and passenger rail. The primary aluminum alloys considered are Al-Mg (5xxx) and Al-Mg-Si (6xxx) due to their mechanical strength, corrosion resistance, and weldability. A major concern in the use of aluminum alloys for lightweight structural applications is fire exposure. Aluminum mechanical properties begin to significantly degrade at temperatures above 300°C. After fire exposure, structural integrity will be governed by the residual, post-fire strength of the aluminum. However, scarce data is available regarding the post-fire mechanical response. The post-fire mechanical properties were characterized for several aluminum alloys: 5083-H116, 6082-T651 plate, and 6082-T6 extrusion. The alloys were exposed to elevated temperatures in a furnace to simulate a fire environment. Tension tests were performed to determine the mechanical response of the alloys. Vickers hardness measurements were also performed on specimens exposed for varying durations and temperatures to quantify the time and temperature-dependent behavior. The observed behaviors were explained in relation to the microstructural strengthening mechanisms for each alloy. Correlations were developed between the mechanical properties and Vickers hardness indentations.
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Hu, Cai, Yu Wang, Yun-Lai Deng, and Jian-Guo Tang. "Effects of Snake Rolling on Mechanical Properties of 2024 Aluminum Alloys." In 2016 International Conference on Mechanics and Materials Science (MMS2016). WORLD SCIENTIFIC, 2017. http://dx.doi.org/10.1142/9789813228177_0075.

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Zinovieva, Olga, Varvara Romanova, Ruslan Balokhonov, and Tatiana Emelyanova. "A review of microstructure and mechanical properties of additively manufactured aluminum alloys." In PROCEEDINGS OF THE INTERNATIONAL CONFERENCE ON PHYSICAL MESOMECHANICS. MATERIALS WITH MULTILEVEL HIERARCHICAL STRUCTURE AND INTELLIGENT MANUFACTURING TECHNOLOGY. AIP Publishing, 2020. http://dx.doi.org/10.1063/5.0035085.

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Labutin, Timur A., Andrey M. Popov, Dmitriy N. Sychev, and Nikita B. Zorov. "Correlation between mechanical properties of aluminum alloys and characteristics of laser-induced plasma." In Advanced Laser Technologies 2007, edited by Ivan A. Shcherbakov, Risto Myllylä, Alexander V. Priezzhev, Matti Kinnunen, Vladimir I. Pustovoy, Mikhail Y. Kirillin, and Alexey P. Popov. SPIE, 2007. http://dx.doi.org/10.1117/12.804115.

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Ramaraju, Ramgopal Varma, Abdullah Bin Ibrahim, Muhammed Arifpin Bin Mansor, and Yaswanth Yattapu. "Structural Properties of Similar and Dissimilar Aluminum Alloy Joints by FSW." In ASME 2014 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2014. http://dx.doi.org/10.1115/imece2014-36960.

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The present study aims to predict the mechanical properties of similar and dissimilar aluminium alloy friction stir Welded joints. The present research also addresses the challenges in joining aluminium alloys Al5083 and Al6061 of 5mm thickness at varying process parameters. A total number of 24 joints have been fabricated with a set of eight joints each for Al6061 (similar), Al5083 (similar) and a combination of Al5083 × Al6061 (dissimilar alloy) as per the experimental plan by Taguchi technique using L8 orthogonal array. The dimensions of the plates are chosen in such a way that the weld length is fixed to 150 mm. The tensile strength and the micro hardness of the welded joints as well as micro structures have been examined. Taguchi technique has been utilized to study the optimized value of the process parameters. The process parameters for joining these have been identified as rotational speeds at 1000 and 1600 rpm, traverse speed 40 and 160mm/min and axial force of 2.5 and 3.5kn.
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Telesheva, Assel. "MECHANICAL PROPERTIES OF ALUMINIUM ALLOYS CRYSTALLISED IN THE CENTRIFUGE." In 18th International Multidisciplinary Scientific GeoConference SGEM2018. Stef92 Technology, 2018. http://dx.doi.org/10.5593/sgem2018/6.1/s24.038.

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Baccouche, Ridha, David Wagner, Andy Sherman, Craig Miller, Susan Ward, and Hikmat Mahmood. "Service Life Aging and Heat Exposure Effects on Aluminum Sheet Alloy Properties and Structural Crashworthiness Under Dynamic Axial Loading." In ASME 2005 International Mechanical Engineering Congress and Exposition. ASMEDC, 2005. http://dx.doi.org/10.1115/imece2005-79925.

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An investigation of the service life aging and heat exposure effects on sheet aluminum alloy properties and structural crashworthiness has been conducted. This research, part of a broader program, consists of investigating five aluminum sheet alloys each of which is subjected to four heat treatments. The aluminum sheet alloys investigated are 6111T4PD, 5754-O, 5182-O, 6022T4E29, and 6022T4. The four heat treatments are 177°C for 30 minutes, 200°C for 15 minutes, 200°C for 2 hours, and 200°C for 24 hours. The 200°C/24 hours treatment simulates the most severe thermal exposure i.e. components adjacent to exhaust pipes and manifolds. All 200°C heat treatments are in addition to the 177°C for 30 minutes. All specimens were subjected to the reference 177°C for 30 minutes treatment. Aluminum rails of hexagonal cross-section were formed for the twenty combinations of aluminum sheet alloys and heat exposures. These twenty formed aluminum rails were then bonded and riveted using Betamate 4601 adhesive and Henrob K50742 self-piercing rivets. Once assembled, these twenty rails were subjected to dynamic axial crushing at a speed of 40 kph (25 mph). Force-Time data was collected and responses were plotted for all tests. Force-Displacement responses were then integrated for the crush energy management and mean axial crush load for each of the aluminum sheet rails. Bar charts were generated to describe the crash loads and energy management behaviors of the various aluminum alloys and associated heat treatments. Service life simulated heat exposure was found to affect the mean crash load and crash energy management of the aluminum structural crash members. The heat exposure effects on the crashworthiness of the sheet aluminum members ranged from a reduction of [−21.6%] to an increase of [+6.8%] in the mean crash load and crash energy management with higher variation observed in the “T4” tempered aluminum alloys.
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Golovashchenko, Sergey F., Al Krause, and Alan J. Gillard. "Incremental Forming for Aluminum Automotive Technology." In ASME 2005 International Mechanical Engineering Congress and Exposition. ASMEDC, 2005. http://dx.doi.org/10.1115/imece2005-81069.

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Insufficient formability can be a major issue in the manufacturing of complex parts, particularly in aluminum alloys that have less formability when compared to steel. The approach which is the subject of this work is to determine the technical feasibility of partial forming, followed by a fast heat treatment and then further deformation. Alloys for consideration would include both 5xxx and 6xxx alloys typically used on interior and exterior automotive panels. The heat treatment regimes used for 6xxx alloys did not affect the material structure, which was confirmed by microstructural analysis and comparison of mechanical properties before and after the heat treatment. Experiments on 5xxx alloys indicated relative improvement of 300% or more. Regimes of material deformation and heat treatment will be presented.
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Reports on the topic "Aluminum alloys – Mechanical properties"

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Verzasconi, S. L. Cryogenic mechanical properties of low density superplastic aluminum alloys. Office of Scientific and Technical Information (OSTI), May 1989. http://dx.doi.org/10.2172/5855723.

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Kooi, D. C., W. Park, and M. R. Hilton. Characterization of Cryogenic Mechanical Properties of Aluminum-Lithium Alloy C-458. Fort Belvoir, VA: Defense Technical Information Center, May 2000. http://dx.doi.org/10.21236/ada380362.

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Sunwoo, A. Weldment mechanical properties of aluminum-copper-lithium alloy, 2090, at ambient and cryogenic temperatures. Office of Scientific and Technical Information (OSTI), May 1990. http://dx.doi.org/10.2172/6787738.

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Peacock, H., and R. Frontroth. Properties of aluminum-uranium alloys. Office of Scientific and Technical Information (OSTI), August 1989. http://dx.doi.org/10.2172/5462232.

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Caskey, Jr, G. R. Mechanical Properties of Uranium Alloys. Office of Scientific and Technical Information (OSTI), October 2002. http://dx.doi.org/10.2172/804673.

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Wallace, J. S., E. R. Jr Fuller, and S. W. Freiman. Mechanical properties of aluminum nitride substrates. Gaithersburg, MD: National Institute of Standards and Technology, 1996. http://dx.doi.org/10.6028/nist.ir.5903.

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Wert, J. A., Jr Starke, and E. A. Processing and Properties of Advanced Aluminum Alloys. Fort Belvoir, VA: Defense Technical Information Center, February 1989. http://dx.doi.org/10.21236/ada205187.

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M. M. Makhlouf, D. Apelian, and L. Wang. Microstructures and properties of aluminum die casting alloys. Office of Scientific and Technical Information (OSTI), October 1998. http://dx.doi.org/10.2172/751030.

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Stevenson, D. A. CrystaL Growth and Mechanical Properties of Semiconductor Alloys. Fort Belvoir, VA: Defense Technical Information Center, April 1988. http://dx.doi.org/10.21236/ada198153.

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Korth, G. E. Mechanical properties of four RSP stainless steel alloys. Office of Scientific and Technical Information (OSTI), December 1996. http://dx.doi.org/10.2172/542018.

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