Restricted accessResearch articleFirst published online 2014-11
Investigation of particle size and reinforcement content on mechanical properties and fracture behavior of A356-Al 2 O 3 composite fabricated by vortex method
The aim of the present study is to investigate the effect of alumina particle size and its amount on relative density, mechanical properties, and fracture behavior of composite. To manufacture micro and nano-composites, alumina particles with various sizes of 50 µm, 10 µm, and 20 nm were separately milled with aluminum powders, and subsequently different volume fractions of milled powders were injected by argon gas into molten alloy and incorporated into A356 matrix by a mechanical stirrer (vortex method). Composites were fabricated at various casting temperatures, viz. 750, 800, and 900℃. Microstructural characterizations revealed that the dendrite size of the Aluminum matrix nano composite (AMNCs) is smaller than that of the non-reinforced alloy. The Scanning electron microscope (SEM) micrographs revealed that the particles were surrounded by silicon eutectic and inclined to move toward inter-dendritic regions. Nano-particles were dispersed uniformly in the matrix when the volume fraction of nano-particles in the composite was less than 3.5 vol.%. The porosity content of the composites increased with increasing volume fraction and decreasing particle size. Also, hardness and tensile strength of the composites improved with decreasing particle size and increasing reinforcement content. The significant improvements in hardness and tensile strength were respectively attained in the nano-composites, reinforced with 1.5 and 2.5 vol.% nano-particles. Alumina particle cracking was observed in the fracture surface of the micro-composites. Agglomerated nano-particles were observed on dendrites in the fracture surface of nano-composites.
SkolianosSKattamisTZ. Tribological properties of SiC-reinforced Al–4.5% Cu–1.5% Mg alloy composites. Mater Sci Eng A1993; 163: 107–113.
4.
AkioKAtsushiOToshiroK. Fabrication process of metal matrix composite with nano-size SiC particle produced by vortex method. J Jpn Inst Light Met1999; 49: 149–154.
5.
KokM. Production and mechanical properties of Al2O3 particle-reinforced 2024 aluminum alloy composites. J Mater Process Technol2005; 161: 381–387.
DominiquePDrewRALTrudeauML. Fabrication and properties of mechanically milled alumina/aluminum nanocomposites. Mater Sci Eng A2010; 527: 527–7605.
8.
Karbalaei AkbariMMirzaeeOBaharvandiH. Fabrication and study on mechanical properties and fracture behavior of nanometric Al2O3 particle-reinforced A356 composites focusing on the parameters of vortex method. J Mater Des2013; 46: 199–205.
9.
RahimianMParvinNEhsaniN. Investigation of particle size and amount of alumina on microstructure and mechanical properties of Al matrix composite made by powder metallurgy. Mater Sci Eng A2010; 527: 1031–1038.
10.
Razavi-TousiSSYazdani-RadRManafiSA. Effect of volume fraction and particle size of alumina reinforcement on compaction and densification behavior of Al–Al2O3 nanocomposites. Mater Sci Eng A2011; 528: 1105–1110.
11.
Razavi HesabiZHafizpourHRSimchiA. An investigation on the compressibility of aluminum/nano-alumina composite powder prepared by blending and mechanical milling. Mater Sci Eng A2007; 454: 89–98.
12.
KhorshidMTJenabali JahromiSAMoshksarMM. Mechanical properties of tri-modal Al matrix composites reinforced by nano- and submicron-sized Al2O3 particulates developed by wet attrition milling and hot extrusion. J Mater Des2010; 31: 3880–3884.
13.
AhamedHSenthilkumarV. Role of nano-size reinforcement and milling on the synthesis of nano-crystalline aluminum alloy composites by mechanical alloying. J Alloys Compd2010; 505: 772–782.
14.
SajjadiSAEzatpourHRMTorabi PariziM. Comparison of microstructure and mechanical properties of A356 aluminum alloy/Al2O3 composites fabricated by stir and compo-casting processes. J Mater Des2011; 34: 106–111.
15.
TongXFangH. Al-TiC composites in-situ-processed by ingot metallurgy and rapid solidification: Part 1 microstructural evolution. Metall Trans A1998; 29: 875–891.
16.
LiXChengX. Ultrasonic-assisted fabrication of metal matrix nanocomposites. J Matter Sci2004; 29: 3211–3212.
17.
HaiSUWenliGZhaohuiF. Processing, microstructure and tensile properties of nano-sized Al2O3 particle reinforced aluminum matrix composites. Matter Des2012; 36: 590–596.
18.
AbdizadehHBaharvandiHRShirvani MoghaddamK. Comparing the effect of processing temperature on microstructure and mechanical behavior of (ZrSiO4 or TiB2)/aluminum composites. Mater Sci Eng A2008; 498: 53–58.
19.
SajjadiSAEzatpourHRBeygiH. Microstructure and mechanical properties of Al–Al2O3 micro and nano composites fabricated by stir casting. Mater Sci Eng A2011; 528: 8765–8771.
20.
AnsaryYAMontazerianMAbdizadehH. Microstructure and mechanical properties of aluminum alloy matrix composite reinforced with nano-particle MgO. J Alloys Compd2009; 884: 400–404.
21.
KarbalaeiAMBaharvandiHMirzaeeO. Nano-sized aluminum oxide reinforced commercial casting A356 alloy matrix: Evaluation of hardness, wear resistance and compressive strength focusing on particle distribution in aluminum matrix. Compos Part: B2013; 52: 262–268.
22.
KarbalaeiAMBaharvandiHMirzaeeO. Fabrication of nano-sized Al2O3 reinforced casting aluminum composite focusing on preparation process of reinforcement powders and evaluation of its properties. Compos Part: B2013; 55: 426–432.
23.
MazaheryAAbdizadehHBaharvandiHR. Development of high performance A356/nano Al2O3 composites. Mater Sci Eng A2009; 518: 61–64.
24.
SokolowskiJHSunXCByczynskiG. The removal of copper-phase segregation and the subsequent improvement in mechanical properties of cast 319 aluminum alloys by a two-stage solution heat treatment. J Mater Process Technol1995; 53: 385–392.
25.
BouvardD. Densification behavior of mixtures of hard and soft powders under pressure. Powder Technol2000; 111: 231–239.
26.
SajjadiSATorabi PariziMEzatpourHR. Fabrication of A356 composite reinforced with micro and nano Al2O3 particles by a developed compocasting method and study of its properties. J Alloys Compd2012; 511: 226–231.
27.
RaviKRPillaiRMAmaranathanKR. Fluidity of aluminum alloys and composites: A review. J Alloys Compd2008; 456: 201–210.
28.
American Society for Metals. Metal handbook. Metals Park (OH), 1973, p.259.
29.
ZhangZChenDL. Contribution of Orowan strengthening effect in particulate reinforced metal matrix nanocomposites. Mater Sci Eng A2008; 483: 148–152.
30.
GeigerALWalkerJA. The processing and properties of discontinuously reinforced aluminum composites. J Miner Met Mater Soc1991; 43: 8–15.
31.
PanQYApelianDAlexandrouAN. Yield behavior of commercial Al-Si alloys in the semisolid state. Metall Mater Trans B2004; 35: 1187–1202.
32.
LanJYangYLiX. Study on bulk aluminum matrix nanocomposite fabricated by ultrasonic dispersion of nano-sized SiC particles in molten aluminum alloy. Mater Sci Eng A2004; 380: 378–383.
33.
Schaefer TA. Chapter 4, Thermomechanical processing and ambient temperature properties of A6061 aluminum 10 volume percent alumina metal matrix composite. MSC Thesis, Naval Post Graduate School, Monterey, CA, 1990.
34.
TahamtanSBoostaniAFNazemiH. Mechanical properties and fracture behavior of thixoformed, rheocast, and gravity-cast A356 alloy. J Alloys Compd2009; 468: 107–114.
35.
LiYTrameshaKChinESC. Comparison of the plastic deformation and failure of A359/Si C and 6061-T6/Al2O3 metal matrix composites under dynamic tension. Mater Sci Eng A2004; 731: 359–370.
36.
WangQG. Microstructural effects on the tensile and fracture behavior of aluminum casting alloys A356/357. Metall Mater Trans A2003; 34: 2887–2889.
37.
LeeKKwonYNLeeS. Correlation of microstructure with mechanical properties and fracture toughness of A356 aluminum alloys fabricated by low-pressure-casting, rheo-casting, and casting–forging processes. Eng Fract Mech2008; 75: 4200–4216.
38.
FadaviBATahamtanS. Effect of a novel thixoforming process on the microstructure and fracture behavior of A356 aluminum alloy. J Mater Des2010; 31: 3769–3776.
39.
NafisiSGhomashchiR. Effects of modification during conventional and semi-solid metal processing of A356 Al-Si alloy. Mater Sci Eng A2006; 415: 273–285.
40.
MazaheryAOstadSM. Plasticity and microstructure of A356 matrix nano composite. J King Saud Univ Eng Sci2013; 25: 41–48.
41.
NguyenQBGuptaM. Enhancing compressive response of AZ31B using nano-Al2O3 and copper additions. J Alloys Compd2010; 490: 382–387.
42.
SastrySKrishnaMUchilJ. A study on damping behaviour of aluminite particulate reinforced ZA-27 alloy metal matrix composites. J Alloys Compd2001; 314: 268–274.
43.
Mondal DP, Ganesh NV, Muneshwar VS, et al. Effect of SiC concentration and strain rate on the compressive deformation behavior of 2014 Al-SiC composite. Mater Sci Eng A 2006; 433: 18–31.
