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International Journal of Metallurgical & Materials Engineering Volume 2 (2016), Article ID 1:IJMME-120, 6 pages
http://dx.doi.org/10.15344/2455-2372/2016/120
Research Article
Mechanical Properties of Friction Stir Processed 1100 Aluminum Reinforced with Rice Husk Ash Silica at Different Rotational Speeds

Hussain Zuhailawati1*, Mohd Noor Halmy1,2, Indra Putra Almanar2, Anasyida Abu Seman1 and Brij Kumar Dhindaw3

1Structural Materials Niche Area, School of Materials and Mineral Resources Engineering, Engineering Campus, Universiti Sains Malaysia,14300 Nibong Tebal, Permatang Pauh, Malaysia
2Faculty of Mechanical Engineering UniversitiTeknologi MARA 13500 Permatang Pauh, Penang, Malaysia
3School of Minerals Metallurgical and Materials Engineering, I. I. T. Bhubaneswar-751007, India
Dr. Hussain Zuhailawati, Structural Materials Niche Area, School of Materials and Mineral Resources Engineering, Engineering Campus, Universiti Sains Malaysia,14300 NibongTebal, Penang, Malaysia, Tel: +6- 04-599-5258, Fax: +6-04-594-1011; E-mail: zuhaila@usm.my
12 November 2015; 04 January 2016; 06 January 2016
Zuhailawati H, Halmy MN, Almanar IP, Seman AA, Dhindaw BK (2016) Mechanical Properties of Friction Stir Processed 1100 Aluminum Reinforced with Rice Husk Ash Silica at Different Rotational Speeds. Int J Metall Mater Eng 2: 120. doi: http://dx.doi.org/10.15344/2455-2372/2016/120
This research was supported by the Ministry of High Education Malaysia and by University Sains Malaysia through a Short Term Grant (60312008) and a scholarship to the first author from Universiti Teknologi MARA (UiTM).

References

  1. Thomas W, Nicholas E, Needham J, Murch M, Templesmith P, et al. (1991) International Patent Application PCT/GB92/02203 and GB Patent Application 9125978.8, UK Patent Office, London, December 6.
  2. Wang W, Shi QY, Liu P, Li HK, Li T (2009) A Novel Way to Produce Bulk SiCp Reinforced Aluminum Metal Matrix Composites by Friction Stir Processing. J Mater Process Technology 209: 2099-2103. View
  3. Morisada Y, Fujii H, Nagaoka T, Fukusumi M, et al. (2006) Effect of Friction Stir Processing with SiC Particles on Microstructure and Hardness of AZ31. Mater Sci Eng: A 433: 50-54. View
  4. Hofmann DC, Vecchio KS (2005) Submerged Friction Stir Processing (SFSP): An Improved Method for Creating Ultra-Fine-Grained Bulk Materials. Mater Sci Eng: A 402: 234-241. View
  5. Lim D, Shibayanagi T, Gerlich A (2009) Synthesis of Multi-Walled CNT Reinforced Aluminium Alloy Composite via Friction Stir Processing. Mater Sci Eng: A 507: 194-199. View
  6. Ke L, Huang C, Xing L, Huang K, et al. (2010) Al-Ni Intermetallic Composites Produced In Situ by Friction Stir Processing. J Alloys Comp 503: 494-499. View
  7. Habeeb GA, Mahmud HB (2010) Study on properties of rice husk ash and its use as cement replacement material. Mat Res 13: 2. View
  8. Hasniyati MR, Zuhailawati H, Ramakrishnan S, Hamid SARSA (2014) Mechanism and Optimization of Titanium Carbide Reinforced Iron Composite Formation through Carbothermal Reduction of Hematite and Anatase. J Alloys Comp 587: 442-450. View
  9. Yusoff M, Othman R, Hussain Z, et al. (2011) Mechanical Alloying and Sintering of Nanistructured Tungsten Carbide-Reinforced Copper Composite and Its Characterization. Materials & Design 32: 3293-3298. View
  10. Long B, Umemoto M, Todaka Y, Othman R, Zuhailawati H (2011) Fabrication of High Strength Cu-NbC Composite Conductor by High Pressure Torsion. Mater Sci Eng: A 528: 1750-1756. View
  11. Arora HS, Singh S, Dhindaw BK (2012) Parametric Study of Friction Stir Processing of Magnesium-Based AE42 Alloy. JMEPEG 2328-2339. View
  12. Arora HS, Singh S, Dhindaw BK (2011) Composite Fabrication Using Friction Stir Processing- A Review. Int J Advanced Manuf Tech 1043-1055. View
  13. Mishra RS, Ma ZY (2005) Friction Stir Welding and Processing. Mater Sci Eng R: Reports 50: 1-78. View
  14. Shaari MR, Hussain Z, Almanar IP, Thuong NV (2014) Comparison of Friction Stir and Tungsten Inert Gas Weldments of AA6061-T6. Advan Mater Res 858: 19-23. View
  15. Lee WB, Yeon YM, Jung SB (2004) Mechanical Properties Related To Microstructural Variation of 6061 Al Alloy Joints by Friction Stir Welding. Mater Trans 45: 1700-1705. View
  16. Lorrain O, Favier V, Zahrouni H, Lawrjaniec D (2010) Understanding The Material Flow Path of Friction Stir Welding Process Using Unthreaded Tools. J Mater Process Technology 210: 603-609. View
  17. Murr LE, Liu G, McClure JC (1997) Dynamic Recrystallization in Friction- Stir Welding of Aluminum Alloy 1100. J. Mater. Science 16: 1801-1803. View
  18. Azizieh M, Kokabi A, Abachi P (2011) Effect of Rotational Speed and Probe Profile on Microstructure and Hardness of AZ31/Al2O3 Nanocomposites Fabricated by Friction Stir Processing. Mater Design 32: 2034-2041. View
  19. Kurt A, Uygur I, Cete E (2011) Surface Modification of Aluminium by Friction Stir Processing. J Mater Process Technology 211: 313-317. View
  20. Mahmoud ER, Takahashi M, Shibayanagi T, Ikeuchi K (2010) Wear Characteristics of Surface-Hybrid-MMCs Layer Fabricated on Aluminum Plate by Friction Stir Processing. Wear 268: 1111-1121. View
  21. Rabinowicz E (1984) The Least Wear. Wear 100: 533-541. View
  22. Ramesh C, Noor Ahmed R, Mujeebu M, Abdullah M, et al. (2009) Development and Preformance Analysis of Novel Cast Copper-SiC-Gr Hybrid Composites. Mater Design 30: 1957-1965. View