Dry sliding tribological behavior and mechanical properties of Al2024-5 wt.%B4C nanocomposite produced by mechanical milling and hot extrusion. Abdollahi, A., Alizadeh, A., & Baharvandi, H. R. Materials & Design, 55:471–481, March, 2014. WOS:000329118700057doi abstract bibtex In this paper, tribological behavior and mechanical properties of nanostructured Al2024 alloy produced by mechanical milling and hot extrusion were investigated before and after adding B4C particles. Mechanical milling was used to synthesize the nanostructured Al2024 in attrition mill under argon atmosphere up to 50 h. A similar process was used to produce Al2024-5 wt.%B4C composite powder. The milled powders were formed by hot pressing and then were exposed to hot extrusion in 750 degrees C with extrusion ratio of 10:1. To study the microstructure of milled powders and hot extruded samples, optical microscopy, transmission electron microscopy and scanning electron microscopy (SEM) equipped with an energy dispersive X-ray spectrometer (EDS) were used. The mechanical properties of samples were also compared together using tension, compression and hardness tests. The wear properties of samples were studied using pin-on-disk apparatus under a 20 N load. The results show that mechanical milling decreases the size of aluminum matrix grains to less than 100 nm. The results of mechanical and wear tests also indicate that mechanical milling and adding B4C particles increase strength, hardness and wear resistance of Al2024 and decrease its ductility remarkably. (C) 2013 Elsevier Ltd. All rights reserved.
@article{abdollahi_dry_2014,
title = {Dry sliding tribological behavior and mechanical properties of {Al2024}-5 wt.\%{B4C} nanocomposite produced by mechanical milling and hot extrusion},
volume = {55},
issn = {0261-3069},
doi = {10.1016/j.matdes.2013.09.024},
abstract = {In this paper, tribological behavior and mechanical properties of nanostructured Al2024 alloy produced by mechanical milling and hot extrusion were investigated before and after adding B4C particles. Mechanical milling was used to synthesize the nanostructured Al2024 in attrition mill under argon atmosphere up to 50 h. A similar process was used to produce Al2024-5 wt.\%B4C composite powder. The milled powders were formed by hot pressing and then were exposed to hot extrusion in 750 degrees C with extrusion ratio of 10:1. To study the microstructure of milled powders and hot extruded samples, optical microscopy, transmission electron microscopy and scanning electron microscopy (SEM) equipped with an energy dispersive X-ray spectrometer (EDS) were used. The mechanical properties of samples were also compared together using tension, compression and hardness tests. The wear properties of samples were studied using pin-on-disk apparatus under a 20 N load. The results show that mechanical milling decreases the size of aluminum matrix grains to less than 100 nm. The results of mechanical and wear tests also indicate that mechanical milling and adding B4C particles increase strength, hardness and wear resistance of Al2024 and decrease its ductility remarkably. (C) 2013 Elsevier Ltd. All rights reserved.},
language = {English},
journal = {Materials \& Design},
author = {Abdollahi, Alireza and Alizadeh, Ali and Baharvandi, Hamid Reza},
month = mar,
year = {2014},
note = {WOS:000329118700057},
keywords = {Aluminum, Hot extrusion, Mechanical milling, Mechanical properties, Tribological behavior, al, aluminum-matrix composites, b4c nanoparticles, cu alloy composites, grain-size, in-situ, powder, reinforced aluminum, tensile properties, wear behavior},
pages = {471--481},
}
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The milled powders were formed by hot pressing and then were exposed to hot extrusion in 750 degrees C with extrusion ratio of 10:1. To study the microstructure of milled powders and hot extruded samples, optical microscopy, transmission electron microscopy and scanning electron microscopy (SEM) equipped with an energy dispersive X-ray spectrometer (EDS) were used. The mechanical properties of samples were also compared together using tension, compression and hardness tests. The wear properties of samples were studied using pin-on-disk apparatus under a 20 N load. The results show that mechanical milling decreases the size of aluminum matrix grains to less than 100 nm. The results of mechanical and wear tests also indicate that mechanical milling and adding B4C particles increase strength, hardness and wear resistance of Al2024 and decrease its ductility remarkably. (C) 2013 Elsevier Ltd. All rights reserved.","language":"English","journal":"Materials & Design","author":[{"propositions":[],"lastnames":["Abdollahi"],"firstnames":["Alireza"],"suffixes":[]},{"propositions":[],"lastnames":["Alizadeh"],"firstnames":["Ali"],"suffixes":[]},{"propositions":[],"lastnames":["Baharvandi"],"firstnames":["Hamid","Reza"],"suffixes":[]}],"month":"March","year":"2014","note":"WOS:000329118700057","keywords":"Aluminum, Hot extrusion, Mechanical milling, Mechanical properties, Tribological behavior, al, aluminum-matrix composites, b4c nanoparticles, cu alloy composites, grain-size, in-situ, powder, reinforced aluminum, tensile properties, wear behavior","pages":"471–481","bibtex":"@article{abdollahi_dry_2014,\n\ttitle = {Dry sliding tribological behavior and mechanical properties of {Al2024}-5 wt.\\%{B4C} nanocomposite produced by mechanical milling and hot extrusion},\n\tvolume = {55},\n\tissn = {0261-3069},\n\tdoi = {10.1016/j.matdes.2013.09.024},\n\tabstract = {In this paper, tribological behavior and mechanical properties of nanostructured Al2024 alloy produced by mechanical milling and hot extrusion were investigated before and after adding B4C particles. Mechanical milling was used to synthesize the nanostructured Al2024 in attrition mill under argon atmosphere up to 50 h. A similar process was used to produce Al2024-5 wt.\\%B4C composite powder. The milled powders were formed by hot pressing and then were exposed to hot extrusion in 750 degrees C with extrusion ratio of 10:1. To study the microstructure of milled powders and hot extruded samples, optical microscopy, transmission electron microscopy and scanning electron microscopy (SEM) equipped with an energy dispersive X-ray spectrometer (EDS) were used. The mechanical properties of samples were also compared together using tension, compression and hardness tests. The wear properties of samples were studied using pin-on-disk apparatus under a 20 N load. The results show that mechanical milling decreases the size of aluminum matrix grains to less than 100 nm. The results of mechanical and wear tests also indicate that mechanical milling and adding B4C particles increase strength, hardness and wear resistance of Al2024 and decrease its ductility remarkably. (C) 2013 Elsevier Ltd. All rights reserved.},\n\tlanguage = {English},\n\tjournal = {Materials \\& Design},\n\tauthor = {Abdollahi, Alireza and Alizadeh, Ali and Baharvandi, Hamid Reza},\n\tmonth = mar,\n\tyear = {2014},\n\tnote = {WOS:000329118700057},\n\tkeywords = {Aluminum, Hot extrusion, Mechanical milling, Mechanical properties, Tribological behavior, al, aluminum-matrix composites, b4c nanoparticles, cu alloy composites, grain-size, in-situ, powder, reinforced aluminum, tensile properties, wear behavior},\n\tpages = {471--481},\n}\n\n","author_short":["Abdollahi, A.","Alizadeh, A.","Baharvandi, H. 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