Laser heat treatment of nickel-based alloys – a review

• Autorzy: Kukliński Mateusz , Szymański Michał , Przestacki Damian

Identyfikatory

DOI

10.2478/amtm-2019-0009

• Języki publikacji: EN

Abstrakty

EN

In this paper researches which focus on laser heat treatment of nickel-based alloys are reviewed. Studies published from 1970s until today are taken into consideration. Publications which focus on influence of laser thermal processing on surface layer condition both on solid materials and predeposited coatings are described. Laser technologies in which additional materials are delivered during the process are not considered. In order to focus on studies investigating microstructural changes resulting mainly from material remelting, laser shock processing is also disregarded.

Słowa kluczowe

EN

nickel; laser; heat treatment; surface; coating

• Wydawca: Wydawnictwo Politechniki Poznańskiej
• Czasopismo: Archives of Mechanical Technology and Materials
• Rocznik: 2019
• Tom: Vol. 39
• Strony: 46--53
• Opis fizyczny: Bibliogr. 27 poz., rys.

Twórcy

autor

Kukliński Mateusz

• Poznań University of Technology, Faculty of Mechanical Engineering and Management, Institute of Mechanical Technology, Piotrowo 3, 60-965 Poznań, Poland

autor

Szymański Michał

• Poznań University of Technology, Faculty of Mechanical Engineering and Management, Institute of Mechanical Technology, Piotrowo 3, 60-965 Poznań, Poland

autor

Przestacki Damian

• Poznań University of Technology, Faculty of Mechanical Engineering and Management, Institute of Mechanical Technology, Piotrowo 3, 60-965 Poznań, Poland

Bibliografia

• [1] Steen W., Mazumder J.,Laser Material Processing. 4th ed, eBook: Springer, 2010.
• [2] Breinan E.M., Kear B.H., Banas C.M., Greenwald L.E., Surface treatment of superalloys by laser skin melting: Superalloys, Metall and Manuf, Proc of IntSymp, 3rd, Seven Springs (1976) 435-450.
• [3] Narasimhan S.L., Copley S.M., van Stryland E.W., Bass M., Solidification of a laser melted nickel-base superalloy, Metallurgical Transactions A 10 (1979) 654-555.
• [4] Gadalov V.N., Ryzhkov F.N., Pozvonkov A.F., Structure and properties of heat-resistant nickel alloys and plasma coatings after laser heat treatment, Metal Science and Heat Treatment 32 (1990) 514-517.
• [5] Nikitin A.A., Potipalova E.V, Travina N.T., Shtanskii D.V., Structure formed by laser heat treatment in heat-resistant nickel alloys and its stability in subsequent aging, Metal Science and Heat Treatment 32 (1990) 517-520.
• [6] Solov'evYu. V., Isakov V.V., Prokopinskaya S.G., Maslenkova E.A., Structure changes and special features of crack formation in high-temperature nickel alloys after laser irradiation, Metal Science and Heat Treatment 37 (1995) 28-32.
• [7] Suh J.-H., Shin J.-K., Kang S-J.L., Lim Y.-S., Kuk I.-H., Kim J.-S., Investigation of IGSCC behavior of sensitized and laser-surface-melted Alloy 600, Materials Science and Engineering A 254 (1998) 67-75.
• [8] Yun S.L., Kim J.S., Hyuk S.K., Effects of sensitization treatment on the evolution of Cr carbides in rapidly solidified Ni-base Alloy 600 by a CO2 laser beam, Materials Science and Engineering A 279 (2000) 192-200.
• [9] Petronić S., Milovanovic D., Milosavljević A., Momcilovic M., Petrusko D., Influence of picosecond laser irradiation on nickel-based superalloy surface microstructure, PhysicaScripta T149 (2012) 014079.
• [10] Liang Y.-J., Wang H.-M., Origin of stray-grain formation and epitaxy loss at substrate during laser surface remelting of single-crystal nickel-based superalloys, Materials and Design 102 (2016) 297-302.
• [11] Liang Y.-J., Cheng X., Wang H.-M., A new microsegregation model for rapid solidification multicomponent alloys and its application to single-crystal nickel-base superalloys of laser rapid directional solidification, ActaMaterialia 118 (2016) 17-27.
• [12] Villermaux F., Tabrizian M., Yahia L'H., Meunier M., Piron D.L., Excimer laser treatment of NiTi shape memory alloy biomaterials, Applied Surface Science 109/110 (1997) 62-66.
• [13] Man H.C., Cui Z.D., Yue T.M., Corrosion properties of laser surface melted NiTi shape memory alloy, ScriptaMaterialia 45 (2001) 1447-1453.
• [14] Cui Z.D., Man H.C., Yang X.J., The corrosion and nickel release behavior of laser-surface melted NiTi shape memory alloy in Hanks, solution, Surface & Coatings Technology 192 (2005) 347-353.
• [15] Chakraborty R., Datta S., Raza M.S., Saha P., A comparative study of surface characterization and corrosion performance properties of laser surface modified biomedical grade nitinol, Applied Surface Science 469 (2019) 753-763.
• [16] Bhat H., Herman H., Coyle R.J., Laser processing of plasma-sprayed NiCr coatings, Lasers in Materials Processing, Conference Proceedings - American Society for Metals: Los Angeles, CA, USA, 1983.
• [17] Enami Y., Takemoto M., Laser treatment of sprayed Ni-Cr coating for enhancing corrosion resistance performance, Corrosion engineering 39 (1990) 465-478.
• [18] Liu F., Liu C., Chen S., Tao X., Xu Z., Wang M., Pulsed Nd:YAG laser post-treatment Ni-based crack-free coating on copper substrate and its wear properties, Surface & Coatings Technology 201 (2007) 6332-6339.
• [19] Chun E.-J., Park C., Nishikawa H., Kim M.-S., Microstructural characterization of Ni-based self-fluxing alloy after selective surface-engineering using diode laser, Applied Surface Science 442 (2018) 726-735.
• [20] Gao Y., Xiong J., Gong D., Li J., Ding M., Improvement of solar absorbing property of Ni-Mo based thermal spray coatings by laser surface treatment, Vacuum 121 (2015) 64-69.
• [21] Panagopoulos C.N., Markaki A.E., Agathocleous P.E., Excimer laser treatment of nickel-coated cast iron, Materials Science and Engineering A 241 (1998) 226-232.
• [22] Matsukawa K., Kataoka M., Morinushi K., The effect of pulsed laser annealing on wear and corrosion properties of electroless Ni-P plating, Tribology Transactions 37 (1994) 573-579.
• [23] García-Alonso M.C., Escudero M.L., López V., Macías A., The corrosion behavior of laser treated Ni-P alloy coatings on mild steel, Corrosion Science 38 (1996) 515-530.
• [24] García-Alonso M.C., López V, Escudero M.L., Macías A., Laser melting treatment of Ni-P surface alloys on mild steel: Influence of initial coating thickness and laser scanning rate, Revista de Metalurgia (Madrid) 33 (1997) 250-257.
• [25] Gholam R.G., Shoja-Razavi R., Hashemi S.H., Isfahani A.R.N., Laser surface alloying of an electroless Ni-P coating with Al-356 substrate, Optics and Lasers in Engineering 46 (2008) 550-557.
• [26] Liu H., Viejo F., Guo R.X., Glenday S., Liu Z., Microstructure and corrosion performance of laser-annealed electroless Ni-W-P coatings, Surface & Coatings Technology 204 (2010) 1549-1555.
• [27] Hashemi S.H., Shoja-Razavi R., Laser Surface heat treatment of electroless Ni-P-SiC coating on Al356 alloy, Optics & Laser Technology 85 (2016) 1-6.

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).