Numerical and experimental analyses of fracture carbon/epoxy composite pipe to steel cylinder with internal pressure

Mohammad Sharifi, Ahmad Reza; Farhadinia, Mahmood; Davar, Ali; Heydari Beni, Mohsen; Eskandari Jam, Jafar

doi:10.22068/jstc.2020.131104.1670

Document Type : Research Paper

Authors

¹ Department of Mechanical Engineering, Malek Ashtar University of Technology, , Iran.

² Department of Mechanical Engineering, Malek Ashtar University of Technology, Tehran, Iran.

10.22068/jstc.2020.131104.1670

Abstract

A mechanical joint has been used to joint metal cylinder to composite pipe made by filament
winding so that by creation bump grooves, on the steel cylinder a guided path for manufacturing
the composite pipe, during filament winding was made. Considering the modulus difference
between composite carbon-epoxy pipe and steel cylinder, it’s predictable that the main
parameter of joint strength under internal pressure is the mentioned modulus difference and
fracture at joint edge. Finite element simulation and with hashin criteria for predicting failure
initiation and progressive damage criteria that definet by UMAT subrotine achieving damage
evolution has been used. The numerical solution results has been compared with experimental
test results which are in good agreement with each other. Besides using microscopic imaging,
the failure zone has been investigated. For numerical modeling the element with various orders
has been used and numerical solution precision and speed, using this elements compared to
experimental results has been investigated and continuum element with reduced integral 3D
high order proposed.

Keywords

References

[1] Xia M., Takayanagi H., and Kemmochi K. “Analysis of multi-layered filament-wound composite pipes under internal pressure,” Composite Structures, 2001. 53(4): p. 483-491.

[2] Wakayama S., et al., “Evaluation of burst strength of FW-FRP composite pipes after impact using pitch-based low-modulus carbon fiber,” Composites Part A: Applied Science and Manufacturing, 2006. 37(11): p. 2002-2010.

[3] Onder A., et al., “Burst failure load of composite pressure vessels,” Composite structures, 2009. 89(1): p. 159-166

[4] Kaynak C. and Mat O. “Uniaxial fatigue behavior of filament-wound glass-fiber/epoxy composite tubes,” Composites Science and Technology, 2001. 61(13): p. 1833-1840.

[5] Rousseau J., Perreux D. and Verdiere N. “The influence of winding patterns on the damage behaviour of filament-wound pipes,” Composites Science and Technology, 1999. 59(9): p. 1439-1449.

[6] Parashar A. and Mertiny P. “Impact of scaling on fracture strength of adhesively bonded fibre-reinforced polymer piping,” Procedia Engineering, 2011. 10: p. 455-459.

[7] Das R. and Baishya N. “Failure analysis of bonded composite pipe joints subjected to internal pressure and axial loading,” Procedia Engineering, 2016. 144: p. 1047-1054.

[8] Kumar S. and Khan M. “An elastic solution for adhesive stresses in multi-material cylindrical joints,” International Journal of Adhesion and Adhesives, 2016. 64: p. 142-152.

[9] Sulu I.Y. and Temiz S. “Failure and stress analysis of internal pressurized composite pipes joined with sleeves,” Journal of Adhesion Science and Technology, 2018. 32(8): p. 816-832.

[10] Kachanov L.M., “Time of the rupture process under creep conditions,” Izy Akad. Nank SSR Otd Tech Nauk, 1958. 8: p. 26-31.

[11] Chaboche J-L., “Continuous damage mechanics—a tool to describe phenomena before crack initiation,” Nuclear Engineering and Design, 1981. 64(2): p. 233-247.

[12] Murakami S., “Notion of continuum damage mechanics and its application to anisotropic creep damage theory,” Journal of Engineering Materials and Technology, 1983. 105(2): p. 99-105.

[13] Ladeveze P. and Lemaitre J. “Damage effective stress in quasi unilateral conditions,” in 16th International congress of theoretical and applied mechanics, Lyngby, Denmark. 1984.

[14] Matzenmiller A., Lubliner J. and Taylor R. “A constitutive model for anisotropic damage in fiber-composites,” Mechanics of materials, 1995. 20(2): p. 125-152.

[15] Hashin Z., “Failure criteria for unidirectional fiber composites,” Journal of applied mechanics, 1980. 47(2): p. 329-334.

[16] Maimí P., et al., “A thermodynamically consistent damage model for advanced composites,” 2006.

[17] Ochoa O.O. and Engblom J.J. “Analysis of progressive failure in composites,” Composites Science and Technology, 1987. 28(2): p. 87-102.

[18] Gotsis P., Chamis C. and Minnetyan L. “Application of progressive fracture analysis for predicting failure envelopes and stress-strain behaviors of composite laminates,” a comparison with experimental results, in Failure Criteria in Fibre-Reinforced-Polymer Composites. 2004, Elsevier. p. 703-725.

[19] Tang X., et al., “Progressive failure analysis of 2× 2 braided composites exhibiting multiscale heterogeneity,” Composites Science and Technology, 2006. 66(14): p. 2580-2590.

[20] Chapelle D. and Perreux D. “Optimal design of a Type 3 hydrogen vessel: Part I—Analytic modelling of the cylindrical section,” International Journal of Hydrogen Energy, 2006. 31(5): p. 627-638.

[21] Cohen D., “Influence of filament winding parameters on composite vessel quality and strength,” Composites Part A: Applied Science and Manufacturing, 1997. 28(12): p. 1035-1047.

[22] Cohen D., Mantell S.C. and Zhao L. “the effect of fiber volume fraction on filament wound composite pressure vessel strength,” Composites Part B: Engineering, 2001. 32(5): p. 413-429.

[23] Perreux D., Robinet P. and Chapelle D. “The effect of internal stress on the identification of the mechanical behaviour of composite pipes,” Composites Part A: Applied Science and Manufacturing, 2006. 37(4): p. 630-635.

[24] Ferry L., et al., “Interaction between plasticity and damage in the behaviour of [+ φ, − φ] n fibre reinforced composite pipes in biaxial loading (internal pressure and tension),” Composites Part B: Engineering, 1998. 29(6): p. 715-723.

[25] Liu P.F. and Zheng J. “Progressive failure analysis of carbon fiber/epoxy composite laminates using continuum damage mechanics,” Materials Science and Engineering: A, 2008. 485(1-2): p. 711-717.

[26] Xu P., Zheng J. and Liu P. “Finite element analysis of burst pressure of composite hydrogen storage vessels,” Materials & Design, 2009. 30(7): p. 2295-2301.

[27] Doh Y. and Hong C. “Progressive failure analysis for filament wound pressure vessel,” Journal of reinforced plastics and composites, 1995. 14(12): p. 1278-1306.

[28] Tzeng J.T. “Dynamic fracture of composite overwrap cylinders,” Journal of reinforced plastics and composites, 2000. 19(1): p. 2-14.

[29] Minnetyan L., Gotsis P.K. and Chamis C.C. “Progressive damage and fracture of unstiffened and stiffened composite pressure vessels,” Journal of reinforced plastics and composites, 1997. 16(18): p. 1711-1724.

[30] Lapczyk I. and Hurtado J.A. “Progressive damage modeling in fiber-reinforced materials,” Composites Part A: Applied Science and Manufacturing, 2007. 38(11): p. 2333-2341.

[31] Liu P., et al., “Numerical simulation and optimal design for composite high-pressure hydrogen storage vessel,” A review. Renewable and Sustainable Energy Reviews, 2012. 16(4): p. 1817-1827.

Journal of Science and Technology of Composites

Numerical and experimental analyses of fracture carbon/epoxy composite pipe to steel cylinder with internal pressure

References

Volume 7, Issue 3
December 2020
Pages 1095-1105

Numerical and experimental analyses of fracture carbon/epoxy composite pipe to steel cylinder with internal pressure

References

Volume 7, Issue 3December 2020Pages 1095-1105

Volume 7, Issue 3
December 2020
Pages 1095-1105