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Tytuł artykułu

Study of the behavior of the Al 2017-A aluminium plate corroded and with horizontal cracks treated by the technique of composite materials

Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
This work presents a comprehensive study consisting of two aspects: a numerical analytical aspect and a laboratory experimental aspect. The numerical study was a three-dimensional finite element numerical analysis of performance of corroded and horizontally cracked aluminium plates, which were repaired by composite patching. The effect of the composite types on the variance of the damaged area of the adhesive (FM-73) and their efficiency on the stress intensity factor were studied. In the experimental study, corroded aluminium plates were prepared and repaired them using technology of the composite. The results showed that the panels that were repaired with composite (boron/epoxy) give values of stress intensity factor (KI) and damaged area ratio (DR) less than the other two studied composites (glass/epoxy and graphite/epoxy), and increase the ultimate strength of plates damage, and this leads to the conclusion that (Boron/epoxy) increases the performance and durability of (Al 2017-A) plates.
Rocznik
Strony
5--24
Opis fizyczny
Bibliogr. 26 poz., rys., tab., wykr.
Twórcy
  • University of AhmedZaban, GIDD Laboratory, Relizane 48000, Algeria
  • University of AhmedZaban, GIDD Laboratory, Relizane 48000, Algeria
Bibliografia
  • 1. N. C. M. Ibrahim, B.Serier, B.Mechab. Analysis of the crack-crack interaction effect initiated in aeronautical structures and repaired by composite patch. Frattura ed Integrità Strutturale, 46 (2018) 140-149.
  • 2. F. Cetisli, M.O. Kaman.Numerical analysis of interface crack problem in composite plates jointed with composite patch.Steel and Composite Structures16(2) (2014) 203-220.
  • 3. J. B. Orsatelli, E. Paroissien, F. Lachaud, S. Schwartz. Bonded flush repairs for aerospace composite structures: A review on modelling strategies and application to repairs optimization, reliability and durability. Composite Structures 304 (2023) 116338.
  • 4. M. Pawlak, T. Górny, L. Dopierała, P. Paczos.The Use of CFRP for Structural Reinforcement—Literature Review. Metals12(9) (2022) 1470.
  • 5. N. Eliaz. Corrosion of Metallic Biomaterials: A Review. Materials (Basel) 12(3)(2019)407.
  • 6. K. Preethi, M. Lavanya. Plant extracts as corrosion inhibitors for aluminum alloy in nacl environment - recent review. Journal of the Chilean Chemical Society 67(2) (2022).
  • 7. K. Xhanari, M. Finšgar, M. K. Marevci, B. Seiti. Green corrosion inhibitors for aluminium and its alloys: A review. RSC Advances 7(44) (2017) 27299-27330.
  • 8. M. Berrahou, K. Amari. Experimental and numerical study on the efficiency of the repair of composite structures cracked and v-notched by different types and shapes of composite material patch. Strojnícky časopis–Journal of Mechanıcal Engıneerıng 72(1) (2022) 1-14.
  • 9. M. Berrahou, K. Amari. Numerical analysis of the repair performance of Notched Cracked Composite Structure repaired by composite patch. Journal of Materials and Engineering Structures 9(3) (2022) 317-326.
  • 10. S. Mohammadi, M. Yousefi, M. Khazaei. A review on composite patch repairs and the most important parameters affecting its efficiency and durability. Journal of Reinforced Plastics and Composites 40(1–2) (2021) 3–15.
  • 11. S. Wang, K. Cao, G. Wang, M. Chen, H. Wang. Preparation and properties of epoxy composites with multi-scale bn sheets. Applied Sciences 12 6171 (2022) 1-10.
  • 12. M.A. Umarfarooq, P.S.S. Gouda, N.R. Banapurmath, I.M. Kittur, T. Khan, I.A. Badruddin, S. Kamangar, M. Hussien. On the residual stresses and fracture toughness of glass/carbon epoxy composites. Materials 15 (2022) 7135.
  • 13. S. Omairey, N. Jayasree, M. Kazilas. Defects and uncertainties of adhesively bonded composite joints. SN Applied Sciences 3(2021) 769.
  • 14. X. Shang, E.A.S. Marques, J.J.M. Machado, R.J.C. carbas, D. jiang, L.F.M. da Silva. Review on techniques to improve the strength of adhesive joints with composite adherends. Composites Part B: Engineering 177 (2019)107363.
  • 15. J. Jacques. Corrosion resistance of alum. [In] J. Jumeau [ed.], Technology of components used in heating, Ultimheat Museum, 2017, pp. 1-4.
  • 16. J. Chen, J. Xiao, J. Poplawsky, F. M. Michel, C. Deng, W. Cai1. The origin of passivity in aluminum-manganese solid solutions. Corrosion Science173 (2020) 108749.
  • 17. S. Mirhashemihaghighi, J. Światowska, V. Maurice, P. Marcus. Corrosion protection of aluminium by ultra-thin atomic layer deposited alumina coatings. Corrosion Science106 (2016) 16-24.
  • 18. L. Yang, W. Du, M. Wu, J. He, G. Yu, S. Wang, Z. Song. Study of the Passivation Film on S32750 Super-Duplex Stainless Steel Exposed in a Simulated Marine Atmosphere. Coatings 12 (2022) 1430.
  • 19. L. Ma, E.M. Pascalidou, F. Wiame, S. Zanna, V. Maurice. Passivation mechanisms and pre-oxidation effects on model surfaces of FeCrNi austenitic stainless steel. Corrosion Science 167 (2020) 108483.
  • 20. B. Z. Jang [ed.], Advanced Polymer Composites: Principles and Applications. ASM International: Materials Park, 1994.
  • 21. R. liu, T. Chen, L. Li, K. Tateishi. A parctial stress intensity factor formula for CFRP repaired steel plates witha central crack. Journal of constructional steel research 152 (2019) 105755.
  • 22. ABAQUS, ABAQUS standard/user’s manual, version 6.5. Hibbit Karlsson & Sorensen,Dassault Systèmes, Inc., Pawtucket, RI, USA. (2007).
  • 23. M. Janssen, J. Zuidema, R. Wanhill [ed.], Fracture mechanics, (2nd Ed.). London. 2004.
  • 24. S. Suresh. Fatigue of Materials, Cambridge University Press, 2004.
  • 25. D. P. Rooke, D. J. Cartwright. Compendium of stress intensity factors, HMSO Ministry of Defence. Procurement Executive,1976.
  • 26. E.F. Rybicki, M.F. Kanninen. A Finite Element Calculation of Stress Intensity Factors by a Modified Crack Closure Integral. Engineering Fracture Mechanics 9(8) (1977) 931-938.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-1397f287-7ea1-4840-8688-2e7c47bbc9f4
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