An Investigation of Stress and Deformation States of Rotating Thick Truncated Conical Shells of Functionally Graded Material
Subject Areas : Engineering
A Thawait
1
(
Department of Mechanical Engineering, Institute of Technology, Guru Ghasidas Vishwavidyalaya, Bilaspur, 495009, India
)
L Sondhi
2
(
Department of Mechanical Engineering, Shri Shankaracharya Technical Campus, SSGI, Bhilai, 490020, India
)
Sh Bhowmick
3
(
Department of Mechanical Engineering, National Institute of Technology (NIT), Raipur, 492010, India
)
Sh Sanyal
4
(
Department of Mechanical Engineering, National Institute of Technology (NIT), Raipur, 492010, India
)
Keywords:
Abstract :
[1] Asemi K., Akhlaghi M., Salehi M., Zad S.K.H., 2011, Analysis of functionally graded thick truncated cone with finite length under hydrostatic internal pressure, Archive of Applied Mechanics 81: 1063-1074.
[2] Bayat M., Sahari B., Saleem M., Dezvareh S., Mohazzab A.H., 2011, Analysis of functionally graded rotating disks with parabolic concave thickness applying an exponential function and the mori-tanaka scheme, IOP Conference Series: Materials Science and Engineering 17: 1-11.
[3] Civalek O., 2006, The determination of frequencies of laminated conical shells via the discrete singular convolution method, Journal of Mechanics of Materials and Structures 1: 163-182.
[4] Civalek O., Gürses M., 2009, Free vibration analysis of rotating cylindrical shells using discrete singular convolution technique, International Journal of Pressure Vessels and Piping 86: 677-683.
[5] Heydarpour Y., Aghdam M.M., 2016, Transient analysis of rotating functionally graded truncated conical shells based on the Lord–Shulman model, Thin-Walled Structures 104: 168-184.
[6] Hua L., 2000, Frequency analysis of rotating truncated circular orthotropic conical shells with different boundary conditions, Composites Science and Technology 60: 2945-2955.
[7] Ma X., Jin G., Xiong Y., Liu Z., 2014, Free and forced vibration analysis of coupled conical–cylindrical shells with arbitrary boundary conditions, International Journal of Mechanical Sciences 88: 122-137.
[8] Malekzadeh P., Daraie M., 2014, Dynamic analysis of functionally graded truncated conical shells subjected to asymmetric moving loads, Thin-Walled Structures 84:1-13.
[9] Nejad M.Z., Jabbari M., Ghannad M., 2015, Elastic analysis of FGM rotating thick truncated conical shells with axially-varying properties under non-uniform pressure loading, Composite Structures 122: 561-569.
[10] Nejad M.Z., Jabbari M., Ghannad M., 2014, Elastic analysis of rotating thick truncated conical shells subjected to uniform pressure using disk form multilayers, ISRN Mechanical Engineering 2014: 1-10.
[11] Nejad M.Z., Jabbari M., Ghannad M., 2014, A semi analytical solution of thick truncated cones using matched asymptotic method and disk form multilayers, Archive of Mechanical Engginering 61: 495-513.
[12] Qinkai H., Fulei C., 2013, Effect of rotation on frequency characteristics of a truncated circular conical Shell, Archive of Applied Mechanics 83: 1789-1800.
[13] Seidi J., Khalili S.M.R., Malekzadeh K., 2015, Temperature-dependent buckling analysis of sandwich truncated conical shells with FG facesheets, Composite Structures 131: 682-691.
[14] Seshu P., 2003, A Text Book of Finite Element Analysis, PHI Learning Pvt, Ltd.
[15] Sofiyev A.H., 2015, Buckling analysis of freely-supported functionally graded truncated conical shells under external pressures, Composite Structures 132: 746-758.
[16] Sofiyev A.H., Kuruoglu N., 2016, Combined effects of elastic foundations and shear stresses on the stability behavior of functionally graded truncated conical shells subjected to uniform external pressures, Thin-Walled Structures 102: 68-79.
[17] Zeighampour H., Beni Y.T., 2014, Analysis of conical shells in the framework of coupled stresses theory, International Journal of Engineering Science 81: 107-122.
[18] Thawait A. K., Sondhi L., Bhowmick S., Sanyal S., 2017, An investigation of stresses and deformation states of clamped rotating functionally graded disks, Journal of Theoretical and Applied Mechanics 55: 189-198.
