Dynamic Analysis of a Thick-Walled Cylindrical Shell Subjected to an Internal Moving Pressure Load and Temperature Effect Based on Higher Order Deformation Theory

Goldenveizer A (1962) Theory of elastic thin shells. Nav Eng J 74(3):582–582

Mirsky I, Hermann G (1958) Axially motions of thick cylindrical shells. Journal of Applied Mechanics-Transactions of the American Society of Mechanical Engineers 25:97–102

Simkins T (1994) Amplification of flexural waves in gun tubes. J Sound Vib 172(2):145–154

Bezverkhii A, Mukoid V (1999) Reaction of thick-walled cylindrical shell to a suddenly applied internal load. Int Appl Mech 30(6):441–445

Beltman W, Shepherd J (2002) Linear elastic response of tubes to internal detonation loading. J Sound Vib 252(4):617–655

Mirzaei M, Mazaheri K, Biglari H (2005) Analytical modeling of the elastic structural response of tubes to internal detonation loading. Int J Press Vessels Pip 82(12):883–895

Mirzaei M, Biglari H, Salavatian M (2006) Analytical and numerical modeling of the transient elasto-dynamic response of a cylindrical tube to internal gaseous detonation. Int J Press Vessels Pip 83(7):531–539

Mirzaei M (2008) On amplification of stress waves in cylindrical tubes under internal dynamic pressures. Int J Mech Sci 50(8):1292–1303

Mirzaei M (2012) Vibrational response of thin tubes to sequential moving pressures. Int J Mech Sci 59(1):44–54

Malekzadeh K, Tajdari M, Zamani SM (2012) dynamic analysis of thick walled cylindrical shell under moving mechanical pressure loading including thermal effect. J Energ Mater 7(4):59–67 ((in Persian))

Mirzaei M, Toorkaman MJ, Akbari R (2015) On vibrational behavior of pulse detonation engine tubes. Aerosp Sci Technol 47:177–190

Azarpazhoo SA, Kazemi SR (2017) Dynamic analysis of long thick cylindrical shell subjected to dynamic internal pressure using high order shear deformation theory. Modares Mechanical Engineering 17(9):427–438 ((in Persian))

Ramezani H, Mirzaei M (2018) Study on effect of boundary conditions in transient dynamic stress analysis of thick cylindrical shells under internal moving pressure. Amirkabir Journal of Mechanical Engineering 50(5):951–960 ((in Persian))

Soykasap O, Mecitoglu Z, Borat O (1996) Dynamic response of composite cylindrical shells to shock loading. Mathematical & Computational Applications 1(1):85–96

Hasheminejad SM, Komeili M (2007) Dynamic response of a thick functionally graded material tube under a moving load. Proc Inst Mech Eng C J Mech Eng Sci 221(12):1545–1554

Shariyat M, Nikkhah M, Kazemi R (2011) Exact and numerical elastodynamic solutions for thick-walled functionally graded cylinders subjected to pressure shocks. Int J Press Vessels Pip 88:75–87

Malekzadeh P, Heydarpour Y (2012) Response of functionally graded cylindrical shells under moving thermo-mechanical loads. Thin-Walled Structures 58:51–66

Isvandzibaei MR, Jamaluddin H, Raja Hamzah RI (2016) Vibration analysis of supported thick-walled cylindrical shell made of functionally graded material under pressure loading. J Vib Control 22(4):1023–1036

Arazm M, Eipakchi H, Ghannad M (2019) Vibrational behavior investigation of axially functionally graded cylindrical shells under moving pressure. Acta Mech 230:3221–3234

Khoshgoftar MJ (2019) Second order shear deformation theory for functionally graded axisymmetric thick shell with variable thickness under non-uniform pressure. Thin-Walled Structures 144:1–12

Eipakchi H,·MahboubiNasrekani F and Ahmadi S, (2020) An analytical approach for the vibration behavior of viscoelastic cylindrical shells under internal moving pressure. Acta Mech 231:3405–3418

Mannani S, Collini L, Arefi M (2023) Mechanical stress and deformation analyses of pressurized cylindrical shells based on a higher-order modeling. Defence Technology 20:24–33

Seilsepour H, Zarastvand M, Talebitooti R (2022) Acoustic insulation characteristics of sandwich composite shell systems with double curvature: the effect of nature of viscoelastic core. J Vib Control 29(5–6):1076–1090

Tang SC (1965) Dynamic response of a tube under moving pressure. J Eng Mech Div 91(5):97–122

Zarastvand M, Ghassabi M, Talebitooti R (2021) Acoustic insulation characteristics of shell structures: a review. Archives of Computational Methods in Engineering 28:505–523

Talebitooti GHD, Zarastvand MR (2017) Multi objective optimization of sound transmission across laminated composite cylindrical shell lined with porous core investigating non-dominated sorting genetic algorithm. Aerosp Sci Technol 69:269–280

Talebitooti and Zarastvand MR, (2018) The effect of nature of porous material on diffuse field acoustic transmission of the sandwich aerospace composite doubly curved shell. Aerosp Sci Technol 78:157–170

Talebitooti ZMR, Gheibi MR (2016) Acoustic transmission through laminated composite cylindrical shell employing third order shear deformation theory in the presence of subsonic flow. Compos Struct 157:95–110

Meirovitch L (1997) Principles and techniques of vibrations, 1st edn. Printice-Hall Inc, USA

Rindler F (2018) Calculus of variations, 1st edn. Springer Publishing, Germany