A Nonlocal First Order Shear Deformation Theory for Vibration Analysis of Size Dependent Functionally Graded Nano beam with Attached Tip Mass: an Exact Solution
Subject Areas : Engineering
M
Ghadiri
1
(Faculty of Engineering, Department of Mechanics, Imam Khomeini International University, Qazvin, Iran)
A
Jafari
2
(Faculty of Engineering, Department of Mechanics, Imam Khomeini International University, Qazvin, Iran)
Keywords:
Abstract :
[1] Iijima S., 1991, Helical microtubules of graphitic carbon, Nature 354: 56-58.
[2] Zhang Y. Q., Liu G. R., Wang J. S., 2004, Small-scale effects on buckling of multi walled carbon nanotubes under axial compression, Physical Review B 70(20): 205430.
[3] Eringen A. C., 1972, Nonlocal polar elastic continua, International Journal of Engineering Science 10(1): 1-16.
[4] Eringen A. C., 1983, On differential equations of nonlocal elasticity and solutions of screw dislocation and surface waves, Journal of Applied Physics 54(9): 4703-4710.
[5] Peddieson J., George R. B., Richard P. M., 2003, Application of nonlocal continuum models to nanotechnology, International Journal of Engineering Science 41(3): 305-312.
[6] Aydogdu M., 2009, A general nonlocal beam theory: its application to Nano beam bending, buckling and vibration, Physica E: Low-Dimensional Systems and Nanostructures 41(9): 1651-1655.
[7] Phadikar J. K., Pradhan S. C., 2010, Variational formulation and finite element analysis for nonlocal elastic Nano beams and Nano plates, Computational Materials Science 49(3): 492-499.
[8] Pradhan S. C., Murmu T., 2010, Application of nonlocal elasticity and DQM in the flap wise bending vibration of a rotating Nano cantilever, Physica E: Low-Dimensional Systems and Nanostructures 42(7): 1944-1949.
[9] Ghorbanpour Arani A., Kolahchi R., Rahimi pour H., Ghaytani M., Vossough H., 2012, Surface stress effects on the bending wave propagation of Nano beams resting on a pasternak foundation, International Conference on Modern Application of Nanotechnology, Belarus.
[10] Ansari R., Gholami R., Sahmani S., 2011, Free vibration analysis of size-dependent functionally graded
microbeams based on the strain gradient Timoshenko beam theory, Composite Structures 94(1): 221-228.
[11] Ebrahimi F., Salari E., 2015, Thermo-mechanical vibration analysis of nonlocal temperature-dependent FG Nano beams with various boundary conditions, Composites Part B: Engineering 78: 272-290.
[12] Srinath L. S., Das Y. C., 1967, Vibration of beams carrying mass , Journal of Applied Mechanics 34(3): 784-785.
Goel R. P., 1976, Free vibrations of a beam mass system with elastically restrained ends, Journal of Sound and Vibration 47: 9-14.
[13] Saito H., Otomi K., 1979, Vibration and stability of elastically supported beams carrying an attached mass axial and tangential loads, Journal of Sound and Vibration 62: 257-266.
[14] Lau J. H., 1981, Fundamental frequency of a constrained beam , Journal of Sound and Vibration 78: 154-157.
[15] Lauara P. A. A., Filipich C., Cortinez V. H., 1987, Vibration of beams and plates carrying concentrated masses, Journal of Sound and Vibration 117: 459-465.
[16] Liu W. H., Yeh F. H., 1987, Free vibration of a restrained-uniform beam with intermediate masses, Journal of Sound and Vibration 117: 555-570.
[17] Maurizi M. J., Belles P. M., 1991, Natural frequencies of the beam-mass system: comparison of the two fundamental theories of beam vibrations, Journal of Sound and Vibration 150: 330-334.
[18] Maurizi M. J., Belles P. M., 1991, Natural frequencies of the beam-mass system: comparison of the two fundamental theories of beam vibrations, Journal of Sound and Vibration 150: 330-334.
[19] Bapat C.N., Bapat C., 1987, Natural frequencies of a beam with non-classical boundary conditions and concentrated masses, Journal of Sound and Vibration 112: 177-182.
[20] Oz H. R., 2000, Calculation of the natural frequencies of a beam-mass system using finite element method, Mathematical and Computational Applications 5: 67-75.
[21] Low K.H.,1991, A comprehensive approach for the Eigen problem of beams with arbitrary boundary conditions, Computers & Structures 39: 671-678.
[22] Kosmatka J.B., 1995, An improved two-node finite element for stability and natural frequencies of axial-loaded Timoshenko beams, Computers & Structures 57:141-149.
[23] Lin H.P., Chang S.C.,2005, Free vibration analysis of multi-span beams with intermediate flexible constraints, Journal of Sound and Vibration 281: 155-169.
[24] Ferreira A.J.M., Fasshauer G.E., 2006, Computation of natural frequencies of shear deformable beams and plates by an RBF-pseudospectral method, Computer Methods in Applied Mechanics and Engineering 196:134-146.
[25] Ruta P., 2006, The application of Chebyshev polynomials to the solution of the nonprismatic Timoshenko beam vibration problem, Journal of Sound and Vibration 296: 243-263.
[26] Laura P.A.A., Pombo J.A., Susemihl E.A., 1974, A note on the vibration of a clamped-free beam with a mass at the free end, Journal of Sound and Vibration 37: 161-168.
[27] Goel R.P., 1976, Free vibrations of a beam-mass system with elastically restrained ends, Journal of Sound and Vibration 47: 9-14.
[28] Parnell L.A., Cobble M.H., 1976, Lateral displacements of a vibrating cantilever beam with a concentrated mass, Journal of Sound and Vibration 44: 499-511.
[29] To C.W.S., 1982, Vibration of a cantilever beam with a base excitation and tip mass, Journal of Sound and Vibration 83: 445-460.
[30] Grant D.A., 1978, The effect of rotary inertia and shear deformation on the frequency and normal mode equations of uniform beams carrying a concentrated mass, Journal of Sound and Vibration 57: 357-365.
[31] Brunch Jr J.C., Mitchell T.P., 1987, Vibrations of a mass-loaded clamped-free Timoshenko beam, Journal of Sound and Vibration 114: 341-345.
[32] Abramovich H., Hamburger O., 1991, Vibration of a cantilever Timoshenko beam with a tip mass, Journal of Sound and Vibration 148: 162-170.
[33] Abramovich H., Hamburger O., 1992,Vibration of a uniform cantilever Timoshenko beam with translational and rotational springs and with a tip mass, Journal of Sound and Vibration 154: 67-80.
[34] Rossi R.E., Laura P.A.A., Avalos D.R., Larrondo H., 1993, Free vibrations of Timoshenko beams carrying elastically mounted concentrated masses, Journal of Sound and Vibration 165: 209-223.
[35] Salarieh H., Ghorashi M., 2006, Free vibration of Timoshenko beam with finite mass rigid tip load and flexural-torsional coupling, International Journal of Mechanical Sciences 48:763-779.
[36] Wu J.S., Hsu S.H., 2007, The discrete methods for free vibration analyses of an immersed beam carrying an eccentric tip mass with rotary inertia, Ocean Engineering 34: 54-68.
[37] Lin H.Y., Tsai Y.C., 2007, Free vibration analysis of a uniform multi-span carrying multiple spring-mass systems, Journal of Sound and Vibration 302: 442-456.
[38] Necla T., 2016, Nonlinear vibration of nanobeam with attached mass at the free end via nonlocal elasticity theory, Microsystem Technologies 22(9): 2349-2359.
[39] Simsek M., 2010, Fundamental frequency of functionally graded beams by using different higher order beam theories, Nuclear Engineering and Design 240(4): 697-705.
[40] Pradhan K.k., Chakraverty S., 2014, Effects of different shear deformation theories on free vibration of functionally graded beams, International Journal of Mechanical Science 82:149-160.
