Evaluating the oxidation resistance of bond coats on thermal barrier coatingsFootnote

Selected from Soldagem & Inspeção 2015 20(4) 479–488.

References

• Lima CRC, Trevisan RE. Aspersão térmica fundamentos e aplicações [Thermal spraying: fundaments and applications] 2a. ed. São Paulo: Artliber; 2007. 152p.
   Google Scholar
• Almeida DS. Estudo de revestimentos cerâmicos sobre substrato metálico, obtidos por deposição físico de vapores por feixe elétrons para aplicação como barreira térmica [tese de doutorado] [Study of ceramic coatings on metal substrates, obtained through electron beam physical vapour deposition for application as a thermal barrier] [ doctorate’s thesis]. São José dos Campos: INPE; 2005. p. 175–177.
   Google Scholar
• Hill MD, Domingues LP. Creating an effective barrier. Ceram Ind. 2003;153(10):17–19.
   Google Scholar
• Hass DD. Thermal barrier coatings via directed vapor deposition [ doctor degree]. Charlottesville: University of Virginia; 2001.
   Google Scholar
• Zhu D, Miller RA. Thermal barrier coating for advanced gas turbine and diesel engines. Ohio: NASA; 1999. 12p. NASA/ TM-1999-209453.
   Google Scholar
• Zhu D, Miller RA, Nagaraj BA, Bruce RW. Thermal conductivity of EBPVD thermal barrier coatings evaluated by a steady–state laser heat flux technique. Ohio: NASA; 2000. 18p. NASA/ TM-2000-210238.
   Google Scholar
• Jamarani F, Korotkin M, Lang RV, et al. Compositionally graded thermal barrier coatings for high temperature aero gas turbine components. Surf Coat Technol. 1992;54–55:58–63.DOI10.1016/S0257-8972(09)90028-7.
   Web of Science ®Google Scholar
• Schulz U. Phase transformation in EB-PVD yttria partially stabilized zirconia TBCs during annealing. J Am Ceram Soc. 2000;4(83):904–910.
   Google Scholar
• Schulz U, Leyens C, Fritscher K, et al. Some recent trends in research and technology of advanced TBCs. Aerosp Sci Technol. 2003;7(1):73–80. DOI:10.1016/S1270-9638(02)00003-2.
   Web of Science ®Google Scholar
• Hejwowski T, Weroński A. The effect of thermal barrier coatings on diesel engine performance. Vacuum. 2002;65(3–4):427–432. DOI:10.1016/S0042-207X(01)00452-3.
   Web of Science ®Google Scholar
• Taymaz I. The effect of thermal barrier coatings on diesel engine performance. Surf Coat Technol. 2007;201(9–11):5249–5252. DOI:10.1016/j.surfcoat.2006.07.123.
   Web of Science ®Google Scholar
• Ribeiro AJRF. Barreiras térmicas compósitas obtidas por projeção térmica [dissertação de mestrado] [Composite thermal barriers obtained through thermal projection] (master’s dissertation) Aveiro: Universidade de Aveiro; 2009. 56p. [cited 2015 Dec 15]. Available from: http://biblioteca.versila.com/2759791
   Google Scholar
• Davis JR. Handbook of thermal spray technology. New York (NY): ASM International; 2004 338p.
   Google Scholar
• Marques PV. Aspersão térmica [Thermal spraying]. Belo Horizonte: Infosolda; 2003 16p.
   Google Scholar
• Fauchais P, Heberlein JVR, Boulos MI. Thermal spray fundamentals: from powder to part. New York (NY): Springer; 2014.10.1007/978-0-387-68991-3
   Google Scholar
• Kreinbuehl R, Kunzmann and Wilmer K. Corrosion protection by arc sprayed al: new developments. Swiss Aluminium; 1974.
   Google Scholar
• Britton CR. Flame spraying with aluminium and aluminium alloys. Al Ind J. 1988;7(10):1–3.
   Google Scholar
• Pawlowski L. The science and engineering of thermal spray coatings. 2a ed. Chichester: Wiley; 2008.10.1002/9780470754085
   Google Scholar
• Associação Brasileira de Normas Técnicas (Brazilian Association of Technical Standards). ABNT NBR ISO 4287:2002. Especificações geométricas do produto (GPS) – Rugosidade: método do perfil – Termos, definições e parâmetros de rugosidade [Geometric product specifications (GPS) – Roughness: profile method – Themes, definitions and parameters of roughness]. Rio de Janeiro: ABNT; 2002.
   Google Scholar
• Comissão de Normas Técnicas (Technical Standards Commission) N-2568. Seleção e aplicação (por aspersão térmica) do alumínio, zinco e suas Ligas como revestimento anticorrosivo [Selecting and applying (using thermal spraying) aluminium, zinc and its Alloys as an anti-corrosive coating] Rio de Janeiro: Petrobrás; 1996. 34p.
   Google Scholar
• Haynes JA, Unocic KA, Lance MJ, Pint BA. Impact of superalloy composition, bond coat roughness and water vapor on TBC lifetime with HVOF NiCoCrAlYHfSi bond coatings. Surf Coat Technol. 2013;237:65–70. DOI:10.1016/j.surfcoat.2013.09.062.
   Web of Science ®Google Scholar
• Knight R, Zhangxiong D, Kim EH, Smith RW, Sahoo P, Bucci D. Influence of bond coat surface characteristics on the performance of TBC systems. In: Coddet C, editor. Thermal spray: meeting the challenges of the 21st century. Ohio: ASM International; 1998. p. 1549–1554.
   Google Scholar
• Lima CRC, Cinca N, Guilemany JM. Study of the high temperature oxidation performance of Thermal Barrier Coatings with HVOF sprayed bond coat and incorporating a PVD ceramic interlayer. Ceram Int. 2012;38(8):6423–6429. DOI:10.1016/j.ceramint.2012.05.016.
   Web of Science ®Google Scholar
• Callister JR, William D. Materials science and engineering: an introduction. 1a ed. Rio de Janeiro: LTC; 2002.
   Google Scholar
• Huang KJ, Chang JT, Davison A, Chen KC, He JL, Lin CK, et al. Thermal cyclic performance of NiAl/Alumina stabilized zircon thermal barrier coatings deposited using a hybrid arc and magnetron sputtering system. Surf Coat Technol. 2006;201(7):3901–3905. DOI:10.1016/j.surfcoat.2006.07.259.
   Web of Science ®Google Scholar
• Reddy A, Hovis DB, Heuer AH, et al. In situ study of oxidation-induced growth strains in a model NiCrAlY bond-coat alloy. Oxid Met. 2007;67(3–4):153–177. DOI:10.1007/s11085-006-9044-8.
   Web of Science ®Google Scholar