Research Article
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Year 2020, , 444 - 453, 30.12.2020
https://doi.org/10.36222/ejt.823161

Abstract

References

  • [1] Koç, V., Demirel, M. (2019). Produced of epoxy resin-mgo polymer matrix composite materials and investigation of pin on disc abrasive wear properties. Firat University Journal of Engineering, 31(1), 1-10.
  • [2] Cunzhu, N., Jiajun, G., Junliang, L., Di, Z. (2008). Investigation on microstructures and interface character of B4C particles reinforced 2024Al matrix composites fabricated by mechanical alloying. Journal of Alloys and Compounds, 454, 118–122.
  • [3] Karagöz, Ş., Yamanoğlu, R., Atapek, Ş. H. (2009). Solidification and Microstructural Characterization on Atomized Powders, Pamukkale University Journal of Engineering Science, 15(3), 309-316.
  • [4] Özel, S., Çelik, E., Turhan, H. (2009). The Investigation of microstructure and mechanical propertıes of Cu-Al/B4C composites produced by using hot pres. e-Journal of New World Sciences Academy Engineering Sciences, 1A0012, 4(1), 106-112.
  • [5] Gökmen, U. (2016). Fabrication and Characterization of Hot Extruded Hybrid Composites Al 2024 Matrix Reinforced with B4C/Al2O3, Journal of Polytechnic, 19(4), 445-453.
  • [6] Topcu, I., Güllüoǧlu, A. N., Bilici, M. K., Gülsoy, H. Ö. (2019). Investigation of wear behavior of Ti-6Al-4V/CNT composites reinforced with carbon nanotubes. Journal of the Faculty of Engineering and Architecture of Gazi University 34(3), 1441-1449. [7] Alman D. E., Hawk, J. A. (1999).The abrasive wear of sintered titanium matrix–ceramic particle reinforced composites, Albany Research Center, USA, 21, 225–229.
  • [8] Chuvildeev, V., Panov, D., Boldin, M., Nokhrin, A., Blagoveshchensky, Y. V., Sakharov, V., Shotin, S., Kotkov, D. (2015). Structure and properties of advanced materials obtained by Spark Plasma Sintering. Acta Astronautica, 109,172-176.
  • [9] Waterhouse, R. B., Iwabuchi. A, (1985). High temperature fretting wear of four titanium alloys, Wear, 106, 303–313.
  • [10] Lee, B. S., Kang, S. (2001). Low-temperature processing of B4C-Al composites viainfiltration technique. Materials Chemistry and Physics, 67, 249-255.
  • [11] Zyang, F. (2002). Multi-Layer Graded Boron Carbide-Aluminum Composites, PhD Thesis, Purdue Universitesi.
  • [12] Leyen, C., Peters, M., Titanium and Alloys, Fundamentals and Applications, Wiley Vch, Köln, Gemany, 2003.
  • [13] ASM Metals Handbook, Powder Metallurgy and Applications, Vol. 7, ASM International, USA, 1998.
  • [14] Donachie, M.J., Titanium a Technical Guide, The Material Information Society, Second Edition, USA, 2000.
  • [15] Henriques, V. A. R., Campos, P. P., Cairo, C. A. A., Bressiani, C. J. (2005). Production of Titanium Alloys for Advanced Aerospace Systems by Powder Metallurgy. Material Research, 8(4), 443-446.
  • [16] Yalçın, B., Varol, R. (2008). Production of Ti-6Al-4V and Ti-5-Al-2.5Fe alloys via powder metalurgy method and ınvestigation of its some mechanical properties. Journal of Polytechnic, 11(3), 235-241.
  • [17] Gok, M.S., Gencel, O., Koc, V., Kucuk, Y., Cay, V. V. (2011). Effect of abrasive particle sizes on abrasive wear of ceramic coatings sprayed by plasma process. Powder Metallurgy and Metal Ceramics, 50(5-6), 322–330.

INVESTIGATION OF WEAR BEHAVIOR OF Ti6Al4V / B4C COMPOSITES PRODUCED BY POWDER METALLURGY

Year 2020, , 444 - 453, 30.12.2020
https://doi.org/10.36222/ejt.823161

Abstract

In this study, Ti6Al4V / B4C Metal Matrix Composite (MMC) was produced using powder metallurgy (PM) method. All powder metal materials mixed by adding 5%, 10% and 15% B4C by weight to the Ti6Al4V matrix were subjected to hot pressing at 950 0C. Pin on disc dry wear test was performed to determine the wear resistance of composite materials produced in different compositions. As a result of the wear tests performed at 300 rpm sliding speed, 300 m sliding distance and three different loads of 5N, 10N, 15N, the effects of Ti6Al4V compound on B4C reinforced wear properties at different rates were investigated. It was determined that composite materials reinforced with B4C powder give better results than unreinforced Ti6Al4V and generally, as the amount of B4C powder increases, the friction coefficient values decrease and the wear resistance increases. In the wear test, it was observed that the friction coefficient of all materials decreased as the load increased. As a result of the changes in B4C reinforcement ratios, differences were observed in wear types and wear track depth. In the experimental studies, it was determined that the wear resistance changes directly with the B4C ratios reinforced by weight and the highest wear resistance is in composite materials with a B4C ratio of 15%.

References

  • [1] Koç, V., Demirel, M. (2019). Produced of epoxy resin-mgo polymer matrix composite materials and investigation of pin on disc abrasive wear properties. Firat University Journal of Engineering, 31(1), 1-10.
  • [2] Cunzhu, N., Jiajun, G., Junliang, L., Di, Z. (2008). Investigation on microstructures and interface character of B4C particles reinforced 2024Al matrix composites fabricated by mechanical alloying. Journal of Alloys and Compounds, 454, 118–122.
  • [3] Karagöz, Ş., Yamanoğlu, R., Atapek, Ş. H. (2009). Solidification and Microstructural Characterization on Atomized Powders, Pamukkale University Journal of Engineering Science, 15(3), 309-316.
  • [4] Özel, S., Çelik, E., Turhan, H. (2009). The Investigation of microstructure and mechanical propertıes of Cu-Al/B4C composites produced by using hot pres. e-Journal of New World Sciences Academy Engineering Sciences, 1A0012, 4(1), 106-112.
  • [5] Gökmen, U. (2016). Fabrication and Characterization of Hot Extruded Hybrid Composites Al 2024 Matrix Reinforced with B4C/Al2O3, Journal of Polytechnic, 19(4), 445-453.
  • [6] Topcu, I., Güllüoǧlu, A. N., Bilici, M. K., Gülsoy, H. Ö. (2019). Investigation of wear behavior of Ti-6Al-4V/CNT composites reinforced with carbon nanotubes. Journal of the Faculty of Engineering and Architecture of Gazi University 34(3), 1441-1449. [7] Alman D. E., Hawk, J. A. (1999).The abrasive wear of sintered titanium matrix–ceramic particle reinforced composites, Albany Research Center, USA, 21, 225–229.
  • [8] Chuvildeev, V., Panov, D., Boldin, M., Nokhrin, A., Blagoveshchensky, Y. V., Sakharov, V., Shotin, S., Kotkov, D. (2015). Structure and properties of advanced materials obtained by Spark Plasma Sintering. Acta Astronautica, 109,172-176.
  • [9] Waterhouse, R. B., Iwabuchi. A, (1985). High temperature fretting wear of four titanium alloys, Wear, 106, 303–313.
  • [10] Lee, B. S., Kang, S. (2001). Low-temperature processing of B4C-Al composites viainfiltration technique. Materials Chemistry and Physics, 67, 249-255.
  • [11] Zyang, F. (2002). Multi-Layer Graded Boron Carbide-Aluminum Composites, PhD Thesis, Purdue Universitesi.
  • [12] Leyen, C., Peters, M., Titanium and Alloys, Fundamentals and Applications, Wiley Vch, Köln, Gemany, 2003.
  • [13] ASM Metals Handbook, Powder Metallurgy and Applications, Vol. 7, ASM International, USA, 1998.
  • [14] Donachie, M.J., Titanium a Technical Guide, The Material Information Society, Second Edition, USA, 2000.
  • [15] Henriques, V. A. R., Campos, P. P., Cairo, C. A. A., Bressiani, C. J. (2005). Production of Titanium Alloys for Advanced Aerospace Systems by Powder Metallurgy. Material Research, 8(4), 443-446.
  • [16] Yalçın, B., Varol, R. (2008). Production of Ti-6Al-4V and Ti-5-Al-2.5Fe alloys via powder metalurgy method and ınvestigation of its some mechanical properties. Journal of Polytechnic, 11(3), 235-241.
  • [17] Gok, M.S., Gencel, O., Koc, V., Kucuk, Y., Cay, V. V. (2011). Effect of abrasive particle sizes on abrasive wear of ceramic coatings sprayed by plasma process. Powder Metallurgy and Metal Ceramics, 50(5-6), 322–330.
There are 16 citations in total.

Details

Primary Language English
Subjects Material Production Technologies
Journal Section Research Article
Authors

Vahdettin Koç 0000-0001-9510-8302

Vedat Veli Çay 0000-0002-2770-4038

Publication Date December 30, 2020
Published in Issue Year 2020

Cite

APA Koç, V., & Çay, V. V. (2020). INVESTIGATION OF WEAR BEHAVIOR OF Ti6Al4V / B4C COMPOSITES PRODUCED BY POWDER METALLURGY. European Journal of Technique (EJT), 10(2), 444-453. https://doi.org/10.36222/ejt.823161

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