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2017 | 81 | 2 | 121-131
Article title

Aluminum and its alloys in the very high cycle fatigue regime

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EN
Abstracts
EN
This paper examines the very high cycle fatigue of aluminum alloys used in engineering applications. Specifically taken into consideration are findings of tests and experiments by some scientists and experts in the field of fatigue of structural materials. The examination of the most common material defects that initiate cracks and causes of fatigue failures in aluminum alloys in the very high cycle regime are reviewed. As aluminum alloys are among the most commonly used structural materials that do not exhibit a fatigue limit at 107 load cycles, it became very important to critically review the tests and experiments of experts in the field in order to ascertain the most causes of failures in these alloys. This paper concluded by suggesting the directions for future works in the very high cycle fatigue of aluminum alloys based on the theoretical review.
Discipline
Year
Volume
81
Issue
2
Pages
121-131
Physical description
Contributors
  • Welding, Related Processes & Technologies, Far Eastern Federal University, Vladivostok, Russia
  • Department of Welding Engineering, Far Eastern Federal University, Vladivostok, Russia
  • Department of Welding Engineering, Far Eastern Federal University, Vladivostok, Russia
  • Department of Welding Engineering, Far Eastern Federal University, Vladivostok, Russia
  • Department of Welding Engineering, Far Eastern Federal University, Vladivostok, Russia
  • Department of Welding Engineering, Far Eastern Federal University, Vladivostok, Russia
References
  • [1] Introduction to Aluminum and its alloys. http://www.aalco.co.uk/datasheets/Aluminium-Alloy_Introduction-to-Aluminium-and-its-alloys_9.ashx
  • [2] 7 things to consider when choosing an aluminum grade. https://www.metalsupermarkets.com/7-things-consider-choosing-aluminum-grade/
  • [3] O. P. Nwachukwu, A. V. Gridasov, E. A. Gridasova. Gigacycle Fatigue of Welded Joints of Structural Materials (A Review). Advanced Engineering Forum 17 (2016) 14-30
  • [4] Q.Y. Wang et al. Gigacycle fatigue behavior of high strength aluminum alloys. Procedia Engineering 2 (2010) 65-70
  • [5] Shoichi Kikuchi et al. Evaluation of Very High Cycle Fatigue Properties of Low Temperature Nitrided Ti-6Al-4V Alloy using Ultrasonic Testing Technology. Key Engineering Materials 664 (2016) 118-127
  • [6] S. Siddique et al. Fatigue Assessment of Laser Additive Manufactured AlSi12 Eutectic Alloy in the Very High Cycle Fatigue (VHCF) Range up to 109 cycles. 5th International Advances in Applied Physics and Materials Science Congress & Exhibition (APMAS2015). Materials Today: Proceedings 3(9)A (2016) 2853-2860
  • [7] M. Janecek et al. The Very High Cycle Fatigue Behaviour of Ti-6Al-4V Alloy. Proceedings of the International Symposium on Physics of Materials (ISPMA13). Acta Physica Polonica A Vol. 128 (2015), No. 4.
  • [8] Sergio Baragetti. Notch Corrosion Fatigue Behavior of Ti-6Al-4V. Materials 7(6) (2014) 4349-4366, doi:10.3390/ma7064349
  • [9] M. K. Khan, Y. J. Liu, Q. Y. Wang, Y. S. Pyun and R. Kayumov. Effect of ultrasonic nanocrystal surface modification on the characteristics of AISI 310 stainless steel up to very high cycle fatigue. Fatigue & Fracture of Engineering Materials & Structures 39(4) (April 2016) 427-438, doi: 10.1111/ffe.12367
  • [10] S. Konovalov, K. Aksenova, V. Gromov, Y. F. Ivanov, O. Semina. The influence of electron beam treatment on Al-Si alloy structure destroyed at high-cycle fatigue. Key Engineering Materials, Applied Physics and Material Applications II 675-676 (2016) 655-659
  • [11] Alexandra Muller et al. Influence of reinforcement geometry on the very high-cycle fatigue behavior of aluminum-matrix-composites. Materials Science Forum 825-826 (2015) 150-157
  • [12] Wycisk E, Siddique S, Herzog D, Walther F and Emmelmann C (2015). Fatigue Performance of Laser Additive Manufactured Ti–6Al–4V in Very High Cycle Fatigue Regime up to 109 Cycles. Frontiers in Matererials 2 (2015) 72. doi:10.3389/fmats.2015.00072
  • [13] A. A. Loktev, E. A. Gridasova, A. V. Sycheva, R. N. Stepanov. Simulation of Railway under Dynamic Loading. Part. Splicing Method of Wave and Contact Solutions. Contemporary Engineering Sciences 8(21) (2015) 955-962 http://dx.doi.org/10.12988/ces.2015.57209
Document Type
article
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Identifiers
YADDA identifier
bwmeta1.element.psjd-481b6472-9071-48a2-8c0d-dc64ecdc0866
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