PSI - Issue 15

Mikhail Perelmuter / Procedia Structural Integrity 15 (2019) 60–66

66

M.N. Perelmuter / Structural Integrity Procedia 00 (2019) 000–000

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Fig. 7. Normal stresses along the crack bridged zone during bonds self healing process.

Fig. 8. Bonds restoration e ff ect. Stress vector at the bridged zone edge versus time, di ff erent bridged zones sizes.

The determination of the model parameters together with validation of the model will allow us widely to apply this model to analysis processes of self-healing in polymers, ceramics, metals and theirs joins. Acknowledgements This work is supported by the Russian Science Foundation under grant No. 19-19-00616. References Alsheghri, A.A., Al-Rub, R.K.A., 2016. Finite element implementation and application of a cohesive zone damage-healing model for self-healing materials. Engineering Fracture Mechanics 163, 1 – 22. Bekas, D., Tsirka, K., Baltzis, D., Paipetis, A., 2016. Self-healing materials: A review of advances in materials, evaluation, characterization and monitoring techniques. Composites Part B: Engineering 87, 92 – 119. Blaiszik, B., Sottos, N., White, S., 2008. Nanocapsules for self-healing materials. Composites Science and Technology 68, 978 – 986. Brochu, A., Craig, S., Reichert, W., 2011. Self-healing biomaterials. J Biomed Mater Res A. 92, 492–506. Burton, D., Gao, X., Brinson, L., 2006. Finite element simulation of a self-healing shape memory alloy composite. Mechanics of Materials 38, 525 – 537. Chhatriwalla, A.K., Cam, A., Unzek, S., Bhatt, D.L., Raymond, R.E., Linco ff , A.M., Whitlow, P.L., Ellis, S.G., Tuzcu, E.M., Kapadia, S.R., 2009. Drug-eluting stent fracture and acute coronary syndrome. Cardiovascular Revascularization Medicine 10, 166 – 171. England, A.H., 1965. A crack between dissimilar media. Journal of Applied Mechanics 32, 400–402. Goldstein, R., Perelmuter, M., 1999. Modeling of bonding at an interface crack. International Journal of Fracture 99, 53–79. Goldstein, R.V., Perelmuter, M.N., 2012. Kinetics of crack formation and growth on the material interface. Mechanics of Solids 47, 400–414. Hopkins, C.G., , McHugh, P.E., McGarry, J.P., 2010. Computational investigation of the delamination of polymer coatings during stent deployment. Annals of Biomedical Engineering 38, 2263–2273. Khawam, A., Flanagan, D.R., 2006. Solid-state kinetic models: Basics and mathematical fundamentals. The Journal of Physical Chemistry B 110, 17315–17328. Lanzara, G., Yoon, Y., Liu, H., Peng, S., Lee, W.I., 2009. Carbon nanotube reservoirs for self-healing materials. Nanotechnology 20, 335704. Ozaki, S., Osada, T., Nakao, W., 2016. Finite element analysis of the damage and healing behavior of self-healing ceramic materials. International Journal of Solids and Structures 100-101, 307 – 318. Perelmuter, M., 2013. Kinetics of interfacial crack bridged zone degradation. Journal of Physics: Conference Series 451, 012–020. Perelmuter, M., 2014. Nonlocal criterion of bridged cracks growth: Weak interface. Journal of the European Ceramic Society 34, 2789–2798. Ponnusami, S.A., Krishnasamy, J., Turteltaub, S., van der Zwaag, S., 2018. A cohesive-zone crack healing model for self-healing materials. International Journal of Solids and Structures 134, 249 – 263. Rice, J.R., 1988. Elastic fracture mechanics concepts for interfacial cracks. Journal of Applied Mechanics 55, 98–103. Tavangarian, F., Hui, D., Li, G., 2018. Crack-healing in ceramics. Composites Part B: Engineering 144, 56 – 87. Trask, R., Williams, G., Bond, I., 2007. Bioinspired self-healing of advanced composite structures using hollow glass fibres. Journal of The Royal Society Interface 4, 363–371. White, S.R., Sottos, N.R., Geubelle, P.H., Moore, J.S., Kessler, M.R., Sriram, S.R., Brown, E.N., Viswanathan, S., 2001. Autonomic healing of polymer composites. Nature 409, 794–797.

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