Production and Characterization of Al-SiC Composites by Mechanical Milling

Yıl 2019, Cilt: 8 Sayı: 1, 227 - 233, 12.03.2019

Doğan Şimşek İjlal Simsek Dursun Özyürek

https://doi.org/10.17798/bitlisfen.441420

Cited By: 4

Öz

This study were
investigated the effect of SiC amount and milling time on microstructure,
density and hardness in the aluminum composites produced by mechanical milling.
In the study, aluminum composites were mechanical milling at different times
(30, 60, 90 and 120 min), adding SiC in different amounts (5%, 10%, 15% and
20%). A high chromium steel balls with a diameter of 6 mm, a ratio of 10:1
ball-powder and 2% stearic acid were used as milling component in the
production of composites in a vibrating mill. The production of composite
powders was carried out in an argon atmosphere. The composite powders produced
were characterized using scanning electron microscopy, EDS analysis, optical
microscope and powder size analyzer. As a result, it was observed that as the
amount of added SiC and milling time increased, the powder size decreased and
the hardness values increased. In addition, as the amount of added SiC
increased, the densities of aluminum composites increased.

Anahtar Kelimeler

Aluminum composite, mechanical milling, powder metallurgy, vibrating mill, SiC

Mekanik Öğütme İle Al-SiC Kompozitlerin Üretimi Ve Karakterizasyonu

Öz

Bu
çalışmada, mekanik öğütme ile üretilen alüminyum kompozitlerde SiC miktarının
ve öğütme süresinin mikro yapı, yoğunluk ve sertlik üzerine etkisi
incelenmiştir. Çalışma kapsamında alüminyum kompozitler, farklı miktarlarda
(%5, %10, %15 ve %20) SiC ilave edilerek farklı sürelerde (30, 60, 90 ve 120
dak) mekanik öğütülmüştür. Titreşimli değirmende yapılan kompozitlerin
üretiminde öğütme elemanı olarak 6 mm çapında yüksek kromlu çelik bilya, 10:1
bilya-toz oranı ve %2 stearik asit (işlem kontrol kimyasalı) kullanılmıştır.
Kompozit tozların üretimi argon ortamında yapılmıştır. Üretilen kompozit tozlar
tarama elektron mikroskobu, EDAX analizleri, optik mikroskop ve toz boyut
analizörü kullanılarak karakterize edilmiştir. Yapılan çalışmalar sonucunda,
ilave edilen SiC miktarı ve öğütme süresi arttıkça toz boyutunda azalma
görülürken, sertlik değerlerinde artış görülmektedir. Bununla birlikte ilave
edilen SiC miktarı arttıkça da alüminyum kompozitlerin yoğunlukları artmaktadır. 

Anahtar Kelimeler

Alüminyum kompozit, mekanik öğütme, toz metalürjisi, titreşimli değirmen, SiC.

Kaynakça

• 1. Prabhu, B., Suryanarayana, C., An, L., Vaidyanathan, R. 2006. Synthesis and Characterization of High Volume Fraction Al–Al2O3 Nanocomposite Powders By High-Energy Milling. Materials Science and Engineering: A, 425(1-2), 192-200.
• 2. Torralba, J. M., Velasco, F., Costa, C. E., Vergara, I., Cáceres, D. 2002. Mechanical Behaviour of The Interphase Between Matrix and Reinforcement Of Al 2014 Matrix Composites Reinforced With (Ni3Al) p. Composites Part A: Applied Science and Manufacturing, 33(3), 427-434.
• 3. Smagorinski, M. E., Tsantrizos, P. G., Grenier, S., Cavasin, A., Brzezinski, T., Kim, G. 1998. The Properties and Microstructure of Al-Based Composites Reinforced With Ceramic Particles. Materials Science and Engineering: A, 244(1), 86-90.
• 4. Erek, H. B., Ozyurek, D., Asan, A. 2017. Electrical Conductivity and Corrosion Performances of In Situ and Ex Situ AA7075 Aluminum Composites. Acta Physica Polonica A, 131(1), 153-155.
• 5. Sundararajan, V. Aluminum Composites In Aerospace Applications. http://satyameva-jayate.net/almmc.htm, (Erişim tarihi: 4.12.2017).
• 6. Mortensen, A., San-Marchi, C., Degischer, H. P. 2002. Glossary of Terms Specific to Metal Matrix Composites. MMC-Assess Thematic Network.
• 7. Rajan, T.P.D., Pillai, R.M., Pai, B.C. 1998. Reinforcement Coatings and Interfaces ın Aluminium Metal Matrix Composites. Journal of Materials Science, 33(14), 3491-3503.
• 8. Yu, P., Mei, Z., Tjong, S.C. 2005. Structure, thermal and mechanical properties of in situ Al-based metal matrix composite reinforced with Al2O3 and TiC submicron particles. Materials Chemistry and Physics, 93(1), 109-116.
• 9. Wannasin, J., Flemings, M.C. 2005. Fabrication of metal matrix composites by a high-pressure centrifugal infiltration process. Journal of Materials Processing Technology, 169(2), 143-149.
• 10. Arifin, A., Sulong, A. B., Muhamad, N., Syarif, J., Ramli, M.I. 2014. Material Processing of Hydroxyapatite and Titanium Alloy (Ha/Ti) Composite as Implant Materials Using Powder Metallurgy: a review. Materials & Design, 55, 165-175.
• 11. Zhao, N., Nash, P., Yang, X. 2005. The Effect of Mechanical Alloying on SiC Distribution and The Properties of 6061 Aluminum Composite. Journal of Materials Processing Technology, 170(3), 586-592.
• 12. Suryanarayana, C. 2001. Mechanical alloying and milling. Progress in materials science, 46(1-2), 1-184.
• 13. Sankar, R., Singh, P. 1998. Synthesis of 7075 Al/SiC Particulate Composite Powders by Mechanical Alloying. Materials Letters, 36(1-4), 201-205.
• 14. Simsek, İ., Yıldırım, M., Tuncay, T., Ozyurek, D., Simsek, D. 2018. Mekanik Alaşimlama/Öğütme Yöntemi İle Üretilen Al-SiC Kompozitlerin İncelenmesi. Technological Applied Sciences, 13(2), 165-171.
• 15. Parvin, N., Assadifard, R., Safarzadeh, P., Sheibani, S., Marashi, P. 2008. Preparation and Mechanical Properties of SiC-Reinforced Al6061 Composite By Mechanical Alloying. Materials Science and Engineering: A, 492(1-2), 134-140.
• 16. Campbell, G. T., Raman, R., Fields, R. J. 2016, August. Optimum Press and Sinter Processing For Aluminum/SiC Composites. Aluminum Powder Metallurgy Conference.