Modeling of cold plastic deformation of the holes made in specimens of shape-memory alloy

Yasnii, Petro Volodymyrovych; Dyvdyk, Oleksandr Volodymyrovych; Iasnii, Volodymyr Petrovych

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Başlık:	Modeling of cold plastic deformation of the holes made in specimens of shape-memory alloy
Yazarlar:	Yasnii, Petro Volodymyrovych Dyvdyk, Oleksandr Volodymyrovych Iasnii, Volodymyr Petrovych
Affiliation:	Ternopil Ivan Pulyui National Technical University
Bibliographic description (Ukraine):	Yasnii, P.V., Dyvdyk O.V., Iasnii V.P. Modeling of Cold Plastic Deformation of the Holes Made in Specimens of Shape-Memory Alloy. Mater Sci (2020). - 2020. Vol. 56, No.1, P. 188-194.
Yayın Tarihi:	29-Kas-2020
Date of entry:	4-Ara-2020
UDC:	539.3
Anahtar kelimeler:	shape-memory effect NiTi alloy phase transformations martensite austenite normal stresses strengthening of the holes
Page range:	188-194
Özet:	The process of cold plastic deformation of a hole in a plate made of shape-memory alloy is simulated by the finite-element method by setting the mechanical characteristics and the temperatures of the onset and termination of direct and reverse phase transformations. By using the ANSYS Workbench software, we determine the distribution of residual stresses in the plate in the vicinity of a functional hole. The highest normal compressive and tensile stresses are formed in the middle part of the plate and at a distance of 2–4 mm from the edge of the hole, respectively.
URI:	http://elartu.tntu.edu.ua/handle/lib/33038
URL for reference material:	https://doi.org/10.1007/s11003-020-00414-0
References (Ukraine):	V. Giurgiutiu and A. Zagrai, “The use of smart materials technologies in radiation environment and nuclear industry,” Proc. SPIE,3985, 855–866 (2000) . H. Wu and L. McD. Schetky, “Industrial applications for shape memory alloys,” in: Proc. of the Internat. Conf. on Shape Memory and Superelastic Technologies, ASM International, Materials Park (2000), pp. 171–182. D. Tarniţǎ, D. Tarniţǎ, N. Bîzdoacǎ, and V. M. Mîndrilǎ, “Properties and medical applications of shape memory alloys,” Rom. J. Morphol. Embryol.,50, No. 1, 15–21 (2009) V. P. Iasnii, H. M. Nykyforchyn, O. T. Tsyrul’nyk, and O. Z. Student, “Specific features of deformation of the nitinol alloy after elec-trolytic hydrogenation,” Fiz.-Khim. Mekh. Mater.,54, No. 4, 124–130 (2018);English translation: Mater. Sci.,54, No. 3, 582–588 (2019) V. P. Iasnii, O. Z. Student, and H. M. Nykyforchyn, “Influence of hydrogenation on the character of fracture of nitinol alloy in tension,” Fiz.-Khim. Mekh. Mater.,55, No. 3, 80–85 (2019); English translation: Mater. Sci.,55, No. 3, 386–391 (2019). V. P. Iasnii, H. M. Nykyforchyn, O. Z. Student, and L. M. Svirska, “Fractographic features of the fatigue fracture of nitinol alloy,” Fiz.-Khim. Mekh. Mater.,55, No. 5, 148–153 (2019); English translation: Mater. Sci.,55, No. 5, 774–779 (2020). Y. Zhang, M. E. Fitzpatrick, and L. Edwards, “Analysis of the residual stress around a cold-expanded fastener hole in a finite plate,” Strain,41, No. 2, 59–70 (2005). Y. Zhang, M. E. Fitzpatrick, and L. Edwards, “Measurement of the residual stresses around a cold expanded hole in an EN8 steel plate using the contour method,” Mater. Sci. Forum Trans. Tech. Publ.,404, 527–534 (2002). B. Kawdi and Dr. N. Shanmukh, “Cold hole expansion process for stress analysis and evaluation of fatigue properties,” J. Mech. Civ. Eng., 21–27 (2009). P. Yasniy, S. Glado, and V. Iasnii, “Lifetime of aircraft alloy plates with cold expanded holes,” Int. J. Fatigue,104, 112–119 (2017). B. Nadri, L. Edwards, M. Fitzpatrick, and A. Lodini, “Measurement of residual stresses following overloading of cold expanded holes using the X-ray diffraction technique and finite element method,” J. Neutron Res.,12, Nos. 1–3, 1–11 (2004). V. Lacarac, D. Smith, and M. Pavier, “The effect of cold expansion on fatigue crack growth from open holes at room and high tem-perature,” Int. J. Fatigue,23, 161–170 (2001). P. V. Yasnii, S. V. Hlad’o, V. V. Skochylyas, and O. I. Semenets, “Formation of residual stresses in plates with functional holes after mandrelling,”Fiz.-Khim. Mekh. Mater., 50, No. 6, 95–98 (2014) English translation: Mater. Sci.,50, No. 6, 877–881 (2015). H. D. Gopalakrishna, H. N. Narasimha Murthy, and M. Krishna, “Cold expansion of holes and resulting fatigue life enhancement and residual stresses in Al 2024 T3 alloy – An experimental study,” Eng. Fail. Anal.,17, No. 2, 361–368 (2010). M. Elajrami, H. Melouki, and F. B. Boukhoulda, “Effect of double cold expansion on the fatigue life of rivet hole,” Int. J. Mining, Metall. Mech. Eng.,1, No. 2, 111–113 (2013). T. Yordan and G. Duncheva, Device and Tool for Cold Expansion of Fastener Holes, Patent USA No. 8915114. B23P9/025 B2, Publ. 12.23.2014. S. Pasta and G. V. Mariotti, “Effect of residual stresses and their redistribution on the fatigue crack growth in cold-worked holes,” in: Proc. of the Internat. Conf. “Crack Paths” (2009), pp. 895–902. J. R. Kennedy and D. J. Larson, Jr., Method of Cold Working Holes Using a Shape Memory Alloy Tool, Patent USA No. 5265456A. B23P9/02, Publ. on 30.11.1993. K.M. Armattoe, C. Bouby, M. Haboussi, and T. Ben, “Modeling of latent heat effects on phase transformation in shape memory alloy thin structures,” Int. J. Solids Struct.,88–89, 293–295 (2016) P. V. Yasnii, O. V. Dyvdyk, V. P. Iasnii. A Tool Made of Shape-Memory Alloy and Intended for Strengthening of Holes in Plates [in Ukrainian], Patent of Ukraine No. 132422, MPK V24V 39/00, Publ. on 25.02.2019, Byul. No. 4. K. Divringi and C. Özcan, Advanced Shape Memory Alloy Material Models for ANSYS [Electronic Resource], Ozen Eng., Sunnyvale, CA (2009), 94085, No. 408. F. Auricchio and L. Petrini, “Improvements and algorithmical considerations on a recent three-dimensional model describing stress-induced solid phase transformations,” Int. J. Numer. Meth. Eng.,55, No. 11, 1255–1284 (2002). V. Iasnii. R. Junga. “Phase Transformations and mechanical properties of the nitinol alloy with shape memory,” Fiz.-Khim. Mekh. Mater.,54, No. 3, 107–111 (2018); English translation: Mater. Sci.,54, No. 3, 406–411 (2018).
Content type:	Article
Koleksiyonlarda Görünür:	Наукові публікації працівників кафедри будівельної механіки

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