2022-Sustainable Industrial Processing Summit
SIPS2022 Volume 18 Intl. Symp on Advanced Materials, Polymers, Composite, Nanomaterials, Nanotechnologies and Manufacturing

Editors:F. Kongoli, F. Marquis, N. Chikhradze, T. Prikhna, M. De Campos, S. Lewis, S. Miller, S. Thomas.
Publisher:Flogen Star OUTREACH
Publication Year:2022
Pages:290 pages
ISBN:978-1-989820-68-1(CD)
ISSN:2291-1227 (Metals and Materials Processing in a Clean Environment Series)
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    Superalloys and Thermal Barrier Coatings for Aeroengine Applications

    Ali Dad Chandio1;
    1NED UNIVERSITY OF ENGINEERING AND TECHNOLOGY, KARACHI, PAKISTAN, Karachi, Pakistan;
    Type of Paper: Invited
    Id Paper: 230
    Topic: 43

    Abstract:

    Nickel based single crystal superalloys have been widely used for blades and vanes of the aeroengine hardware [1, 2, 3]. The main goal of these alloys is to provide high temperature strength owing to its γ-Ni/γ’-Ni3Al structure under aggressive working environment [1, 2, 3]. However, alloying elements used do not provide desired oxidation resistance to the components [1]. In order to provide optimum oxidation resistance and improve engine working efficiency, a system of the coating is applied which is commonly known as thermal barrier coating (TBC) system [1, 2, 3]. In general, TBC system comprises of two layers i.e. ceramic topcoat (TC) and an underlying metallic layer as a bond coat (BC). However, there is one additional layer between BC and TC grown either during service or manufacturing is known as thermally grown oxide (TGO) i.e., Al2O3. One of the crucial parts of the TBC system is the nickel aluminides (βNiAl) layer that is used as BC material [4, 5]. Most often, such a layer governs the TC life in the absence of foreign object damage [2]. For example, various modes of the failures are reported in literature such rumpling, stress and interdiffusion [1,2,5]. In this work, bond coat and associated trends are highlighted in the light of experimental observations.

    Keywords:

    Energy efficiency; Environment; New and advanced materials; Superalloys; Thermal Barrier Coatings; Bond Coat; Reactive Elements; Diffusion Barrier; Oxidation Resistance

    References:

    [1] Reed RC, The superalloys: Fundamentals and Applications, , . 2006: Cambridge University Press.
    [2] Clarke, D., and Levi CG. , Material design for the next generation thermal barrier coatings. Annual Review of Materials Research, 2003. 33(1): p. 383-417.
    [3] Tong, L., Y. Dengzun, and Z. Chungen, Low-temperature Formation of Aluminide Coatings on Ni-base Superalloys by Pack Cementation Process. Chinese Journal of Aeronautics, 2010. 23(3): p. 381-385.
    [4] Liu, C., et al. (2020). "The al-enriched γ’-Ni3Al-base bond coat for thermal barrier coating applications." 108523.
    [5] Mehboob, G., et al. (2020). "A review on failure mechanism of thermal barrier coatings and strategies to extend their lifetime." 46(7): 8497-8521.

    Cite this article as:

    Chandio A. (2022). Superalloys and Thermal Barrier Coatings for Aeroengine Applications. In F. Kongoli, F. Marquis, N. Chikhradze, T. Prikhna, M. De Campos, S. Lewis, S. Miller, S. Thomas. (Eds.), Sustainable Industrial Processing Summit SIPS2022 Volume 18 Intl. Symp on Advanced Materials, Polymers, Composite, Nanomaterials, Nanotechnologies and Manufacturing (pp. 139-140). Montreal, Canada: FLOGEN Star Outreach