Numerical and Experimental Investigation on Post-buckling ‎Behavior of Stiffened Cylindrical Shells with Cutout subject to ‎Uniform Axial Compression

[1] Eslami, M.R., Buckling and post-buckling of beams, plates, and shells, Springer, Switzerland, 2018

[2] Kiarasi, F., Babaei, M., Dimitri, R., Tornabene, F., Hygrothermal modeling of the buckling behavior of sandwich plates with nanocomposite face sheets resting on a Pasternak foundation, Continuum Mechanics and Thermodynamics, 2020, 1-22, https://doi.org/10.1007/s00161-020-00929-6.

[3] Van Dyke, P., Stresses about a circular hole in a cylindrical shell, AIAA Journal, 3(9), 1965, 1733-1742.‏

[4] Tennyson, R.C., The effects of unreinforced circular cutouts on the buckling of circular cylindrical shells under axial compression, J. Eng. Ind., 90(4), 1968, 541-546.

[5] Brogan, F., Almroth, B.O., Buckling of cylinders with cutouts, AIAA Journal,8(2), 1970, 236-240.‏

‏[6] Almroth, B.O., Brogan, F.A., Marlowe, M.B., Stability analysis of cylinders with circular cutouts, AIAA Journal, 11(11), 1973, 1582-1584.‏

[7] Toda, S., Buckling of cylinders with cutouts under axial compression, Experimental Mechanics, 23(4), 1983, 414-417.

[8] Hilburger, M., Starnes, J., Waas, A., The response of composite cylindrical shells with cutouts and subjected to internal pressure and axial compression loads, 39th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference and Exhibit, 1998.‏

[9] Estekanchi, H.E., Vafai, A., On the buckling of cylindrical shells with through cracks under axial load, Thin-Walled Structures, 35(4), 1999, 255-274.‏

[10] Frulloni, E., Kenny, J.M., Conti, P., Torre, L., Experimental study and finite element analysis of the elastic instability of composite lattice structures for aeronautic applications, Composite Structures, 78(4), 2007, 519-528.‏

[11] Rahimi, G.H., Poursaeidi, E., Parametric study of plastic strength of cylindrical shells with cutout under bending moment and axial loading, 2004.

[12] Ghorbanpour Arani, A., Loghman, A., Mosallaei Barzoki, A.A., Kolahchi, R., Elastic buckling analysis of ring and stringer-stiffened cylindrical shells under general pressure and axial compression via the Ritz method, Journal of Solid Mechanics, 2(4), 2010, 332-347.‏

[13] Han, H., Cheng, J., Taheri, F., Pegg, N., Numerical and experimental investigations of the response of aluminum cylinders with a cutout subject to axial compression, Thin-Walled Structures, 44(2), 2006, 254-270.‏

[14] Buermann, P., Rolfes, R., Tebmer, J., Schagerl, M., A semi-analytical model for local post-buckling analysis of stringer-and frame-stiffened cylindrical panels, Thin-Walled Structures, 44(1), 2006, 102-114.‏

[15] Shariati, M., Mahdizadeh Rokhi, M., Buckling of steel cylindrical shells with an elliptical cutout, International Journal of Steel Structures, 10(2), 2010, 193-205

[16] Shariati, M., Mahdizadeh Rokhi, M., Numerical and experimental investigations on buckling of steel cylindrical shells with elliptical cutout subject to axial compression, Thin-Walled Structures, 46(11), 2008, 1251-1261.‏

[17] Shariati, M., Mahdizadeh Rokhi, M., Investigation of buckling of Steel cylindrical shells with elliptical cutout under bending moment, International Review of Mechanical Engineering, 3, 2009, 1-7.

[18] Bisagni, C., Cordisco, P., Post-buckling and collapse experiments of stiffened composite cylindrical shells subjected to axial loading and torque, Composite Structures, 73(2), 2006, 138-149.‏

[19] Yazdani, M., Rahimi, G.H., The effects of helical ribs’ number and grid types on the buckling of thin-walled GFRP-stiffened shells under axial loading, Journal of Reinforced Plastics and Composites, 29(17), 2010, 2568-2575.‏

[20] Shahani, A.R., Mohammadjani, R., Evaluation of FEM instability loads of stiffened cylindrical shells and comparison them with analytical results, Modares Mechanical Engineering, 15(6), 2015, 58-68

[21] Cheng Z., Niu, J., Zhang, Q., Zhao, C., Xie, J., Buckling behavior of a thin-walled cylinder shell with the cutout imperfections, Mechanics of Advanced Materials and Structures, 26(18), 2019, 1536-1542.‏

[22] Jiao, P., Chen, Z., Xu, T., Tang, X., Su, W., Effects of ringed stiffener on the buckling behavior of cylindrical shells with cutout under axial compression: Experimental and numerical investigation, Thin-Walled Structures, 123, 2018, 232-243.‏

[23] Brunesi, E., Nascimbene, R., Effects of structural openings on the buckling strength of cylindrical shells, Advances in Structural Engineering, 21(16), 2018, 2466-2482.‏

‏[24] Liang, K., Ruess, M., Nonlinear buckling analysis of the conical and cylindrical shells using the SGL strain based reduced order model and the PHC method, Aerospace Science and Technology, 55, 2016, 103-110.

[25] Vu-Bac, N., Duong, T.X., Lahmer, T., Zhuang, X., Sauer, R.A., Park, H.S., Rabczuk, T.A., NURBS-based inverse analysis for reconstruction of nonlinear deformations of thin shell structures, Computer Methods in Applied Mechanics and Engineering, 331, 2018, 427-455.

[26] ‏Testing, American Society for, Materials, Subcommittee A01, 13 Mechanical, Chemical Testing, Processing Methods of Steel Products, and Processes, Standard test methods and definitions for mechanical testing of steel products: ASTM International, 2003.

بی مایند...