@article{scholars7271, note = {cited By 0}, year = {2016}, doi = {10.1007/978-3-319-03197-2{$_6$}}, publisher = {Springer Science and Business Media B.V.}, journal = {Engineering Materials}, title = {Non-linear Finite Element Analysis of Nanotubes}, pages = {107--131}, url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-85126724490&doi=10.1007\%2f978-3-319-03197-2\%5f6&partnerID=40&md5=8bd564579aa7fac3cd34151c43c4c3c0}, keywords = {Elasticity; Finite element method; Harmonic analysis; Loads (forces); Modal analysis; Spectrum analysis; Static analysis; Strain; Structural analysis; Yarn, Buckling analysis; Dynamics analysis; Explicit dynamic analyse; Explicit dynamics; Main menu; Nonlinear finite element analyses (FEA); Nonlinear material models; Nonlinear material properties; Spectra analysis; Stress/strain, File editors}, abstract = {Structural analysis is possibly the utmost common application of the finite element method with several options available. For example, in ANSYS there are seven types of structural analyses available: static analysis, modal analysis, harmonic analysis, harmonic analysis, spectrum analysis, buckling analysis, explicit dynamic analysis and others for special-purpose features 1. Static analysis has wider applications and is used to determine the displacements, stresses, strains, and forces in structures or components caused by loads that do not induce significant inertia and damping effects. Steady loading and response conditions are assumed; that is, the loads and the structure{\^a}??s response are assumed to vary slowly with respect to time. The kinds of loading that can be applied in a static analysis include: externally applied forces and pressures, steady-state inertial forces (such as gravity or rotational velocity), imposed (nonzero) displacements, temperatures (for thermal strain) and others 2. {\^A}{\copyright} 2016, Springer International Publishing Switzerland.}, author = {Awang, M. and Mohammadpour, E. and Muhammad, I. D.}, issn = {16121317} }