Buckling Performances of Spherical Caps Under Uniform External Pressure

Yueyang Wang; Jian Zhang; Wenxian Tang

doi:10.1007/s11804-020-00125-7

Journal of Marine Science and Application ›› 2020, Vol. 19 ›› Issue (1) : 96 -100. DOI: 10.1007/s11804-020-00125-7

Research Article

Buckling Performances of Spherical Caps Under Uniform External Pressure

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Abstract

This study aims to experimentally and numerically examine the buckling performances of stainless steel spherical caps under uniform external pressure. Three laboratory-scale caps were fabricated, measured, and tested. The buckling behaviors of these caps were investigated through experiments and three numerical methods, namely, nonlinear Riks algorithm, nonlinear bifurcation, and linear elastic analysis. The buckling of equal-radius caps was numerically analyzed with different methods to identify their applicability under different wall thicknesses. The results obtained from the nonlinear Riks algorithm are in good agreement with the experimental results, which means the nonlinear Riks algorithm can accurately predict the buckling performances of spherical caps, including the magnitude of critical buckling loads and the deformation of post-buckling modes. The nonlinear bifurcation algorithm is only suitable for predicting the buckling loads of ultra-thin or large-span caps, and the linear buckling method is inappropriate for predicting the buckling of metal spherical caps.

Keywords

Spherical cap / Stainless steel / Buckling / External pressure / Bifurcation buckling / Critical buckling

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Yueyang Wang, Jian Zhang, Wenxian Tang. Buckling Performances of Spherical Caps Under Uniform External Pressure. Journal of Marine Science and Application, 2020, 19(1): 96-100 DOI:10.1007/s11804-020-00125-7

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References

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[1]	ASTM International ASTM D638-14: standard test method for tensile properties of plastics, 2003, West Conshohocken: ASTM International

[2]	Błachut J. Buckling of multilayered metal domes. Thin-Walled Struct, 2009, 47: 1429-1438

[3]	Błachut J (2014) Externally pressurized toricones-buckling tests. Shell structures–theory and applications, vol. 3, CRC-Press Taylor & Francis, Boca Raton, 183–186

[4]	Błachut J. Locally flattened or dented domes under external pressure. Thin-Walled Struct, 2015, 97: 44-52

[5]	Błachut J. Buckling of composite domes with localised imperfections and subjected to external pressure. Compos Struct, 2016, 153: 746-754

[6]	Błachut J. Buckling of externally pressurized steel toriconical shells. Int J Press Vessel Pip, 2016, 144: 25-34

[7]	Błachut J, Galletly GD. Buckling strength of imperfect spherical caps—some remarks. AIAA J, 1990, 28(7): 1317-1319

[8]	Błachut J, Galletly GD. Buckling strength of imperfect steel hemispheres. Thin-Walled Struct, 1995, 23: 1-20

[9]	Błachut J, Galletly GD, Moreton DN. Buckling of near-perfect steel torispherical and hemispherical shells subjected to external pressure. AIAA J, 1990, 28(11): 1971-1975

[10]	Findlay GE, Timmins W. Toriconical heads: a parametric study of elastic stresses and implications on design. Int J Press Vessel Pip, 1984, 15(3): 213-227

[11]	Galletly GD, Kruzelecki J, Moffat DG, Warrington B. Buckling of shallow torispherical domes subjected to external pressure–a comparison of experiment, theory, and design codes. J Strain Anal Eng Des, 1987, 22(3): 163-175

[12]	Gerasimidis S, Virot E, Hutchinson JW, Rubinstein SM. On establishing buckling knockdowns for imperfection-sensitive shell structures. J Appl Mech, 2018, 85: 091010-1-091010-14

[13]	Ifayefunmi O. Buckling behavior of axially compressed cylindrical shells: comparison of theoretical and experimental data. Thin-Walled Struct, 2016, 98: 558-564

[14]	Jasion P, Magnucki K. Elastic buckling of Cassini ovaloidal shells under external pressure – theoretical study. Archives of Mechanics, 2015, 67(2): 179-192

[15]	Jasion P, Magnucki K. Stability of an ellipsoidal head with a central nozzle under axial load. Arch Civ Eng, 2015, 61(2): 89-98

[16]	Krivoshapko SN. Research on general and axisymmetric ellipsoidal shells used as domes, pressure vessels, and tanks. Appl Mech Rev, 2007, 60(6): 336-355

[17]	Lee A, Marthelot J, Hutchinson JW, Reis PM. The geometric role of precisely engineered imperfections on the critical buckling load of spherical elastic shells. J Appl Mech, 2016, 83: 111005-1-111005-11

[18]	López Jiménez F, Marthelot J, Lee A, Hutchinson JW, Reis PM. Technical brief: knockdown factor for the buckling of spherical shells containing large-amplitude geometric defects. J Appl Mech, 2017, 84: 034501-1-034501-4

[19]	Magnucki K, Jasion P, Rodak M. Strength and buckling of an untypical dished head of a cylindrical pressure vessel. Int J Press Vessel Pip, 2018, 161: 17-21

[20]	Tripathi SM, Anup S, Muthukumar R. Effect of geometrical parameters on mode shape and critical buckling load of dished shells under external pressure. Thin-Walled Struct, 2016, 106: 218-227

[21]	Wagner HNR, Hühne C, Niemann S. Robust knockdown factors for the design of spherical shells under external pressure: development and validation. Int J Mech Sci, 2018, 141: 58-77

[22]	Wang YY, Tang WX, Zhang J, Zhang S, Chen Y. Buckling of imperfect spherical caps with fixed boundary under uniform external pressure. Mar Struct, 2019, 65: 1-11

[23]	Warrington B (1984) The buckling of torispherical shells under external pressure. PhD thesis, The University of Liverpool, Liverpool. DOI: https://doi.org/10.1016/j.ijpvp.2018.02.003

[24]	Zhang J, Zhu BY, Wang F, Tang WX, Wang WB, Zhang M. Buckling of prolate egg-shaped domes under hydrostatic external pressure. Thin-Walled Struct, 2017, 119: 296-303

[25]	Zhang M, Tang WX, Wang F, Zhang J, Cui WC, Chen Y. Buckling of bi-segment spherical shells under hydrostatic external pressure. Thin-Walled Struct, 2017, 120: 1-8

[26]	Zhang J, Wang YY, Wang F, Tang WX. Buckling of stainless steel spherical caps subjected to uniform external pressure. Ships Offshore Struc, 2018, 13(7): 779-785

[27]	Zhang J, Wang YY, Tang WX, Zhu YM, Zhao XL. Buckling of externally pressurised spherical caps with wall-thickness reduction. Thin-Walled Struct, 2019, 136: 129-137