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Ferromolibden ve ferrobor takviyeli lazer kaplamaların aşınma karakteristiği ve mikroyapısı

Year 2019, Volume: 10 Issue: 3, 1009 - 1017, 29.09.2019
https://doi.org/10.24012/dumf.511737

Abstract

Lazer kaplama yöntemi ile kalıp yüzeylerinde
aşınmaya dirençli bir tabaka oluşumu veya kalıpta meydana gelen bölgesel
aşınmaların tamiratı gerçekleştirilebilmektedir. Bu çalışmada, AISI 4140
çeliğinin aşınma direncini geliştirmek amacıyla ferromolibden (FeMo) ve
ferrobor (FeB) takviyeli demir esaslı kaplamalar lazer yöntemi ile
gerçekleştirilmiştir. Kaplamaların aşınma direnci ball-on-disk aşınma testiyle
tespit edilmiştir. Mikroyapı incelemeleri hem optik mikroskop hem de taramalı
elektron mikroskobu altında gerçekleştirilmiştir. Sertlik ölçümü sonucunda FeB
takviyeli kaplamanın FeMo takviyeli kaplamaya göre daha yüksek sertliğe sahip
olduğu görülmüştür. Artan kaplama sertliği aşınma direncini artırarak FeB
takviyeli kaplamada daha az malzeme kaybı meydana getirmiştir.    

References

  • Badisch, E., Mitterer, C., (2003). Abrasive wear of high speed steels: Influence of abrasive particles and primary carbides on wear resistance, Tribology International, 36(10), 765-770.
  • Balasubramanian, V., Varahamoorthy, R., Ramachandran, C.S., Muralidharan, C., (2009). Selection of Welding Process for Hardfacing on Carbon Steels Based on Quantitative and Qualitative Factors, International Journal of Advanced Manufacturing Technology, 40, 887- 897.
  • Bodnar, R.L., Hansen, S.S., (1994). Effects of austenite grain size and cooling rate on Widmanstätten ferrite formation in low-alloy steels, Metallurgical and Materials Transactions A, 25(4), 665-675.
  • Birger, E.M., Moskvitin, G.V., Polyakov, A.N., Arkhipov, V.E., (2011). Industrial laser cladding: current state and future, Welding International, 25(3), 234-243.
  • Buytoz, S., Orhan, A., Gur, A. K., Caligulu, U., (2013). Microstructural Development of Fe–Cr–C and B 4 C Powder Alloy Coating on Stainless Steel by Plasma-Transferred Arc Weld Surfacing, Arabian Journal for Science and Engineering, 38(8), 2197-2204.
  • Cay, V.V., Ozan, S., Gök, M.S., (2011). The effect of hydrogen shielding gas on microstructure and abrasive wear behavior in the surface modification process using the tungsten inert gas method, Journal of Coatings Technology and Research, 8(1), 97-105.
  • Chen, J.M., Chun, G., Zhou J.S., (2012). Microstructure and Tribological Properties of Laser Cladding Fe-Based Coating on Pure Ti Substrate, Transactions of Nonferrous Metals Society of China, 22(9), 2171–2178.
  • Chandrasekar, M., Shivalingappa, D., Channankaiah. D., (2016). Recent Developments in Cladding Process – A Review, International Journal for Innovative Research in Science & Technology, 2(10), 310-315.
  • Dai, S., Zuo, D.W., Fang, C., Zhu, L., Cheng, H., Gao, Y.X., Li, W.W., (2016). Characteration of Laser Cladded Fe-Mn-Cr Alloy Coatings Modified by Plasma Nitriding, Materials Transactions, 57(4), 539-543.
  • Du, B., (2013). Fabrication of In-situ Fe-Ti-B composite coating by laser cladding, Surface Review and Letters, 20(3-4), 1-8.
  • Fu, Z.K., Ding, H.H., Wang, W.J., Liu, Q.Y., Guo, J., Zhu, M.H., (2015). Investigation on microstructure and wear characteristic of laser cladding Fe-based alloy on wheel/rail materials, Wear, 330, 592-599.
  • Gasik, M., eds. (2013). Handbook of ferroalloys: theory and technology, Chapter 12: Technology of Molybdenum Ferroalloys, 387-396, Butterworth- Heinemann.
  • Luo, K.Y., Xu, X., Zhao, Z., Zhao, S.S., Cheng, Z.G., Lu, J.Z., (2019). Microstructural evolution and characteristics of bonding zone in multilayer laser cladding of Fe-based coating, Journal of Materials Processing Technology, 263, 50-58.
  • Luyckx, S., Love, A., (2004). The relationship between the abrasion resistance and the hardness of WC-Co alloys, Journal of the South African Institute of Mining and Metallurgy, 104(10), 579- 582.
  • Maropoulos, S., Karagiannis, S., Ridley, N., (2007). Factors affecting prior austenite grain size in low alloy steel, Journal of materials science, 42(4), 1309-1320.
  • Toms, T., (2013). The Application of Laser Cladding to Mechanical Component Repair, Renovation and Regeneration in Katalinic, B., Tekic, Z., eds, DAAAM International Scientific Book, DAAAM International, 587-608, Vienna, Austria.
  • Wang, X.H., Han, F., Liu, X.M., Qu, S.Y., Zou, Z.D., (2008). Effect of molybdenum on the microstructure and wear resistance of Fe-based hardfacing coatings, Materials Science and Engineering: A, 489(1-2), 193-200.
  • Zanzarin, S., Bengtsson, S., Molinari, A., (2016). Study of dilution in laser cladding of a carbon steel substrate with Co alloy powders, Powder Metallurgy, 59(1), 85-94.
  • Zhang, M., Liu, S.S., Luo, S.X., Qu, K.L., (2018). Effect of molybdenum on the high-temperature properties of TiC-TiB2 reinforced Fe-based composite laser cladding coatings, Journal of Alloys and Compounds, 742, 383-390.
Year 2019, Volume: 10 Issue: 3, 1009 - 1017, 29.09.2019
https://doi.org/10.24012/dumf.511737

Abstract

References

  • Badisch, E., Mitterer, C., (2003). Abrasive wear of high speed steels: Influence of abrasive particles and primary carbides on wear resistance, Tribology International, 36(10), 765-770.
  • Balasubramanian, V., Varahamoorthy, R., Ramachandran, C.S., Muralidharan, C., (2009). Selection of Welding Process for Hardfacing on Carbon Steels Based on Quantitative and Qualitative Factors, International Journal of Advanced Manufacturing Technology, 40, 887- 897.
  • Bodnar, R.L., Hansen, S.S., (1994). Effects of austenite grain size and cooling rate on Widmanstätten ferrite formation in low-alloy steels, Metallurgical and Materials Transactions A, 25(4), 665-675.
  • Birger, E.M., Moskvitin, G.V., Polyakov, A.N., Arkhipov, V.E., (2011). Industrial laser cladding: current state and future, Welding International, 25(3), 234-243.
  • Buytoz, S., Orhan, A., Gur, A. K., Caligulu, U., (2013). Microstructural Development of Fe–Cr–C and B 4 C Powder Alloy Coating on Stainless Steel by Plasma-Transferred Arc Weld Surfacing, Arabian Journal for Science and Engineering, 38(8), 2197-2204.
  • Cay, V.V., Ozan, S., Gök, M.S., (2011). The effect of hydrogen shielding gas on microstructure and abrasive wear behavior in the surface modification process using the tungsten inert gas method, Journal of Coatings Technology and Research, 8(1), 97-105.
  • Chen, J.M., Chun, G., Zhou J.S., (2012). Microstructure and Tribological Properties of Laser Cladding Fe-Based Coating on Pure Ti Substrate, Transactions of Nonferrous Metals Society of China, 22(9), 2171–2178.
  • Chandrasekar, M., Shivalingappa, D., Channankaiah. D., (2016). Recent Developments in Cladding Process – A Review, International Journal for Innovative Research in Science & Technology, 2(10), 310-315.
  • Dai, S., Zuo, D.W., Fang, C., Zhu, L., Cheng, H., Gao, Y.X., Li, W.W., (2016). Characteration of Laser Cladded Fe-Mn-Cr Alloy Coatings Modified by Plasma Nitriding, Materials Transactions, 57(4), 539-543.
  • Du, B., (2013). Fabrication of In-situ Fe-Ti-B composite coating by laser cladding, Surface Review and Letters, 20(3-4), 1-8.
  • Fu, Z.K., Ding, H.H., Wang, W.J., Liu, Q.Y., Guo, J., Zhu, M.H., (2015). Investigation on microstructure and wear characteristic of laser cladding Fe-based alloy on wheel/rail materials, Wear, 330, 592-599.
  • Gasik, M., eds. (2013). Handbook of ferroalloys: theory and technology, Chapter 12: Technology of Molybdenum Ferroalloys, 387-396, Butterworth- Heinemann.
  • Luo, K.Y., Xu, X., Zhao, Z., Zhao, S.S., Cheng, Z.G., Lu, J.Z., (2019). Microstructural evolution and characteristics of bonding zone in multilayer laser cladding of Fe-based coating, Journal of Materials Processing Technology, 263, 50-58.
  • Luyckx, S., Love, A., (2004). The relationship between the abrasion resistance and the hardness of WC-Co alloys, Journal of the South African Institute of Mining and Metallurgy, 104(10), 579- 582.
  • Maropoulos, S., Karagiannis, S., Ridley, N., (2007). Factors affecting prior austenite grain size in low alloy steel, Journal of materials science, 42(4), 1309-1320.
  • Toms, T., (2013). The Application of Laser Cladding to Mechanical Component Repair, Renovation and Regeneration in Katalinic, B., Tekic, Z., eds, DAAAM International Scientific Book, DAAAM International, 587-608, Vienna, Austria.
  • Wang, X.H., Han, F., Liu, X.M., Qu, S.Y., Zou, Z.D., (2008). Effect of molybdenum on the microstructure and wear resistance of Fe-based hardfacing coatings, Materials Science and Engineering: A, 489(1-2), 193-200.
  • Zanzarin, S., Bengtsson, S., Molinari, A., (2016). Study of dilution in laser cladding of a carbon steel substrate with Co alloy powders, Powder Metallurgy, 59(1), 85-94.
  • Zhang, M., Liu, S.S., Luo, S.X., Qu, K.L., (2018). Effect of molybdenum on the high-temperature properties of TiC-TiB2 reinforced Fe-based composite laser cladding coatings, Journal of Alloys and Compounds, 742, 383-390.
There are 19 citations in total.

Details

Primary Language Turkish
Journal Section Articles
Authors

Hülya Durmuş 0000-0002-7270-562X

Nilay Çömez 0000-0002-6432-6582

Canser Gül 0000-0002-1339-936X

Melis Yuddaşkal This is me 0000-0002-8774-3848

Recep Onur Uzun This is me 0000-0002-1042-0493

Publication Date September 29, 2019
Submission Date January 11, 2019
Published in Issue Year 2019 Volume: 10 Issue: 3

Cite

IEEE H. Durmuş, N. Çömez, C. Gül, M. Yuddaşkal, and R. O. Uzun, “Ferromolibden ve ferrobor takviyeli lazer kaplamaların aşınma karakteristiği ve mikroyapısı”, DUJE, vol. 10, no. 3, pp. 1009–1017, 2019, doi: 10.24012/dumf.511737.
DUJE tarafından yayınlanan tüm makaleler, Creative Commons Atıf 4.0 Uluslararası Lisansı ile lisanslanmıştır. Bu, orijinal eser ve kaynağın uygun şekilde belirtilmesi koşuluyla, herkesin eseri kopyalamasına, yeniden dağıtmasına, yeniden düzenlemesine, iletmesine ve uyarlamasına izin verir. 24456