PSI - Issue 7

Julius N. Domfang Ngnekou et al. / Procedia Structural Integrity 7 (2017) 75–83 Julius N. Domfang Ngnekou et Al./ Structural Integrity Procedia 00 (2017) 000–000

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5. Acknowledgement The authors gratefully acknowledges funding provided by Zodiac Aerospace and French National Research and Technology Association (ANRT). This work partially pertains to the French Government program "Investissements d'Avenir" (LABEX INTERACTIFS, reference ANR-11-LABX-0017-01).This work has been partially supported by « Nouvelle Aquitaine » Region and by European Structural and Investment Funds (ERDF reference: P-2016-BAFE 94/95). Thanks to Thierry ROUGE-CARRASSAT for his fruitful comments on the manuscript. 6. References [1] Nesma T. Aboulkhair, Ian Maskery, Chris Tuck, Ian Ashcroft, and Nicola M. Everitt. Improving the fatigue behaviour of a selectively laser melted aluminium alloy: Influence of heat treatment and surface quality. Material and Design , 104:174–182, 2016. [2] Erhard Brandl, Ulrike Heckenberger, Vitus Holzinger, and Damien Buchbinder. Additive manufactured alsi10mg samples using selective laser melting (slm): Microstructure, high cycle fatigue, and fracture behavior. Materials and Design , 34:159–169, 2012. [3] Y. X. GAO, J. Z. YI, P. D. LEE, and T. C. LINDLEY. The effect of porosity on the fatigue life of cast aluminium-silicon alloys. Fatigue & Fracture of Engineering Material & Structure , 27:559–570, 2004. [4] Mohamed Iben Houria. Experimental investigation and modeling the fatigue life of a cast aluminium alloy A356-T6 under multiaxial loading . phdthesis, Université de Poitiers (France), 2015. [5] Mohamed Iben Houria, Yves Nadot, , Raouf Fathallah, Matthew Roy, and Daan M. Maijer. Influence of casting defect and sdas on the multiaxial fatigue behaviour of a356-t6 alloy including mean stress effect. International Journal of Fatigue , 2015. [6] K. Kempen, L.Thijs, J. Van Humbeeck, , and J.-P. Kruth. Mechanical properties of alsi10mg produced by selective laser melting. In LANE 2012 , volume 39, pages 439–446. Physics Procedia, 2012. [7] Wei Li, Shua Li, Jie Liu, Ang Zhang, Yan Zhou, Qing song Wei, Chunze Yan, and Yusheng Shi. Effect of heat treatment on alsi10mg alloy fabricated by selective laser melting: Microstructure evolution, mechanical properties and fracture mechanism. Material Science & Engineering , A 663:116–125, 2016. [8] I. Maskery, N. T. Aboulkhair, C. Truck, and R.D Wildman. Fatigue performance enhancement of selective laser melted aluminium alloy by heat treatment. 2016. [9] Tang Ming. Inclusion, porosity, and Fatigue of AlSi10Mg Parts Produced by Selective Laser Melting . phdthesis, Melon University, 2017. [10] Y. Murakami and M. Endo. Effects of defects, inclusions and inhomogeneities on fatigue strength. International Journal of Fatigue , 16:163–182, 1994. [11] M.J. Roy, Y. Nadot, C. Nadot-Martin, P.-G. Bardin, and D.M. Maijer. Multiaxial kitagawa analysis of a356 t6. International Journal of Fatigue , 33, 2011. [12] Lore Thijs, Karolien Kempen, Jean-Pierre Kruth, and Jan Van Humbeeck. Fine-structured aluminium products with controllable texture by selective laser melting of pre-alloyed alsi10mg powder. Acta Materialia , 61:1809–1819, 2013. [13] Q.G. Wang, D. Apelian, and D.A. Lados. Fatigue behavior of a356-t6 aluminum cast alloys. part i. effect of casting defects. Journal of Light Metals 1 , 1:73–84, 2001. [14] JIANGWen-ming, FAN Zi-tian, and LIU De-jun. Microstructure, tensile properties and fractography of a356 alloy under as-cast and t6 obtained with expendable pattern shell casting process. rans. Nonferrous Met. Soc. China , 22:7–13, 2012.