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Applied Mathematics and Mechanics >

2018 , Vol. 39 >Issue 12: 1805 - 1824

DOI: https://doi.org/10.1007/s10483-018-2395-9

Articles

Semi-analytic solution of Eringen's two-phase local/nonlocal model for Euler-Bernoulli beam with axial force

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  • 1. Facility Design and Instrumentation Institute, China Aerodynamics Research and Development Center, Mianyang 621000, Sichuan Province, China;
    2. State Key Laboratory of Mechanics and Control of Mechanical Structures, Nanjing University of Aeronautics and Astronautics, Nanjing 210016, China

Received date: 2018-02-27

  Revised date: 2018-07-03

  Online published: 2018-12-01

Supported by

Project supported by the National Natural Science Foundation of China (No. 11472130)

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Abstract

Eringen's two-phase local/nonlocal model is applied to an Euler-Bernoulli nanobeam considering the bending-induced axial force, where the contribution of the axial force to bending moment is calculated on the deformed state. Basic equations for the corresponding one-dimensional beam problem are obtained by degenerating from the three-dimensional nonlocal elastic equations. Semi-analytic solutions are then presented for a clamped-clamped beam subject to a concentrated force and a uniformly distributed load, respectively. Except for the traditional essential boundary conditions and those required to be satisfied by transferring an integral equation to its equivalent differential form, additional boundary conditions are needed and should be chosen with great caution, since numerical results reveal that non-unique solutions might exist for a nonlinear problem if inappropriate boundary conditions are used. The validity of the solutions is examined by plotting both sides of the original integro-differential governing equation of deflection and studying the error between both sides. Besides, an increase in the internal characteristic length would cause an increase in the deflection and axial force of the beam.

Key words: direct control; simplified form; absolute stability; necessaryand sufficient condition; unique solution; axial force; nonlocal elasticity; internal characteristic length; size effect; nanobeam

Cite this article

Licheng MENG, Dajun ZOU, Huan LAI, Zili GUO, Xianzhong HE, Zhijun XIE, Cunfa GAO . Semi-analytic solution of Eringen's two-phase local/nonlocal model for Euler-Bernoulli beam with axial force[J]. Applied Mathematics and Mechanics, 2018 , 39(12) : 1805 -1824 . DOI: 10.1007/s10483-018-2395-9

References

[1] BEHERA, L. and CHAKRAVERTY, S. Recent researches on nonlocal elasticity theory in the vibration of carbon nanotubes using beam modes:a review. Archives of Computational Methods in Engineering, 24(3), 481-491(2017)
[2] BABIĆ, B., FURER, J., SAHOO, S., FARHANGFAR, Sh., and SCHÖNENBERGER, C. Intrinsic thermal vibrations of suspended doubly clamped single-wall carbon nanotubes. Nano Letters, 3(11), 1577-1580(2003)
[3] CHOWDHURY, R., ADHIKARI, S., WANG, C. Y., and SCARPA, F. A molecular mechanics approach for the vibration for single-walled carbon nanotubes. Computational Materials Science, 48(4), 730-735(2010)
[4] ZHANG, Y. Y., WANG, C. M., and TAN, V. B. C. Assessment of Timoshenko beam models for vibrational behavior of single-walled carbon nanotubes using molecular dynamics. Advances in Applied Mathematics and Mechanics, 1(1), 89-106(2009)
[5] KRÖNER, E. Elasticity theory of materials with long-range cohesive forces. International Journal of Solids and Structures, 3(5), 731-742(1967)
[6] KRUMHANSL, J. A. Some considerations of the relation between solid state physics and generalized continuum mechanics. Mechanics of Generalized Continua, Springer, Berlin/Heidelberg, 298-311(1968)
[7] KUNIN, I. A. The theory of elastic media with microstructure and the theory of dislocations. Mechanics of Generalized Continua, Springer, Berlin/Heidelberg, 321-329(1968)
[8] ERINGEN, A. C. and EDELEN, D. G. B. On nonlocal elasticity. International Journal of Engineering Science, 10(3), 233-248(1972)
[9] ERINGEN, A. C. Theory of nonlocal thermoelasticity. International Journal of Engineering Science, 12(12), 1063-1077(1974)
[10] ERINGEN, A. C. Theory of nonlocal elasticity and some applications. Res Mechanica, 21(4), 313-342(1987)
[11] ERINGEN, A. C. Nonlocal Continuum Field Theories, Springer, New York (2002)
[12] PEDDIESON, J., BUCHANAN, G. R., and MCNITT, R. P. Application of nonlocal continuum models to nanotechnology. International Journal of Engineering Science, 41(3/4/5), 305-312(2003)
[13] CHALLAMEL, N. and WANG, C. M. The small length scale effect for a non-local cantilever beam:a paradox solved. Nanotechnology, 19(34), 345703(2008)
[14] LI, C. On Theory, Modeling and Solutions for Statics and Dynamics of a Nanobeam and Nanobeam-Like Structure Based on Nonlocal Elasticity Theory (in Chinese), Ph. D. dissertation, University of Science and Technology of China (2011)
[15] LAM, D. C. C., YANG, F., CHONG, A. C. M., WANG, J., and TONG, P. Experiments and theory in strain gradient elasticity. Journal of the Mechanics and Physics of Solids, 51(8), 1477-1508(2003)
[16] LI, C. Y. and CHOU, T. W. Vibration behaviors of multiwalled-carbon-nanotube-based nanomechanical resonators. Applied Physics Letters, 84(1), 121-123(2004)
[17] LIM, C. W. On the truth of nanoscale for nanobeams based on nonlocal elastic stress field theory:equilibrium, governing equation and static deflection. Applied Mathematics and Mechanics (English Edition), 31(1), 37-54(2010) https://doi.org/10.1007/s10483-010-0105-7
[18] LI, C., YAO, L. Q., CHEN, W. Q., and LI, S. Comments on nonlocal effects in nano-cantilever beams. International Journal of Engineering Science, 87, 47-57(2015)
[19] POLIZZOTTO, C. Nonlocal elasticity and related variational problems. International Journal of Solids and Structures, 38(42), 7359-7380(2001)
[20] KHODABAKHSHI, P. and REDDY, J. N. A unified integro-differential nonlocal model. International Journal of Engineering Science, 95, 60-75(2015)
[21] FERNÁNDEZ-SÁEZ, J., ZAERA, R., LOYA, J. A., and REDDY, J. N. Bending of Euler-Bernoulli beams using Eringen's integral formulation:a paradox resolved. International Journal of Engineering Science, 99, 107-116(2016)
[22] TUNA, M. and KIRCA, M. Exact solution of Eringen's nonlocal integral model for bending of Euler-Bernoulli and Timoshenko beams. International Journal of Engineering Science, 105, 80-92(2016)
[23] ROMANO, G. and BARRETTA, R. Comment on the paper "Exact solution of Eringen's nonlocal model for bending of Euler-Bernoulli and Timoshenko beams" by Meral Tuna & Mesut Kirca. International Journal of Engineering Science, 109, 240-242(2016)
[24] TUNA, M. and KIRCA, M. Respond to the comment letter by Romano and Barretta on the paper "Exact solution of Eringen's nonlocal model for bending of Euler-Bernoulli and Timoshenko beams". International Journal of Engineering Science, 116, 141-144(2017)
[25] WANG, Y. B., ZHU, X. W., and DAI, H. H. Exact solutions for the static bending of EulerBernoulli beams using Eringen's two-phase local/nonlocal model. AIP Advances, 6(8), 085114(2016)
[26] ROMANO, G. and BARRETTA, R. Nonlocal elasticity in nanobeams:the stress-driven integral model. International Journal of Engineering Science, 115, 14-27(2017)
[27] ROMANO, G., BARRETTA, R., DIACO, M., and SCIARRA, F. M. D. Constitutive boundary conditions and paradoxes in nonlocal elastic nanobeams. International Journal of Mechanical Sciences, 121, 151-156(2017)
[28] ROMANO, G., BARRETTA, R., and DIACO, M. On nonlocal integral models for elastic nanobeams. International Journal of Mechanical Sciences, 131-132, 490-499(2017)
[29] ROMANO, G., LUCIANO, R., BARRETTA, R., and DIACO, M. Nonlocal integral elasticity in nanostructures, mixtures, boundary effects and limit behaviours. Continuum Mechanics and Thermodynamics, 30(3), 641-655(2018)
[30] BARRETTA, R., DIACO, M., FEO, L., LUCIANO, R., SCIARRA, F. M. D., and PENNA, R. Stress-driven integral elastic theory for torsion of nano-beams. Mechanics Research Communications, 87, 35-41(2018)
[31] BARRETTA, R., FAGHIDIAN, S. A., LUCIANO, R., MEDAGLIA, C. M., and PENNA, R. Stress-driven two-phase integral elasticity for torsion of nano-beams. Composites Part B, 145, 62-69(2018)
[32] BARRETTA, R., ČANADIJA, M., LUCIANO, R., and SCIARRA, F. M. D. Stress-driven modeling of nonlocal thermoelastic behavior of nanobeams. International Journal of Engineering Science, 126, 53-67(2018)
[33] OSKOUIE, M. F., ANSARI, R., and ROUHI, H. Bending of Euler-Bernoulli nanobeams based on the strain-driven and stress-driven nonlocal integralmodels:a numerical approach. Acta Mechanica Sinica, 34, 871-882(2018)
[34] YAO, Y. Analysis of Several Problem in Nonlocal Continuum Mechanics (in Chinese), Ph. D. dissertation, Nanjing University of Aeronautics and Astronautics, 11-30(2010)
[35] COWPER, G. R. The shear coefficient in Timoshenko's beam theory. Journal of Applied Mechanics, 87(4), 621-635(1966)
[36] HUANG, Z. X. New points of view on the nonlocal field theory and their applications to the fracture mechanics (I)-fundamental theory. Applied Mathematics and Mechanics (English Edition), 18(1), 45-54(1997) https://doi.org/10.1007/BF02457500
[37] HUANG, Z. X. New points of view on the nonlocal field theory and their applications to the fracture mechanics (Ⅱ)-re-discuss nonlinear constitutive equations of nonlocal thermoelastic bodies. Applied Mathematics and Mechanics (English Edition), 20(7), 764-772(1999) https://doi.org/10.1007/BF02454898
[38] HUANG, Z. X. New points of view on the nonlocal field theory and their applications to the fracture mechanics (Ⅲ)-re-discuss the linear theory of nonlocal elasticity. Applied Mathematics and Mechanics (English Edition), 20(11), 1286-1290(1999) https://doi.org/10.1007/BF02463798
[39] ALTAN, S. B. Uniqueness of initial-boundary value problems in nonlocal elasticity. International Journal of Solid Structures, 25(11), 1271-1278(1989)
[40] POLYANIN, A. D. and MANZHIROV, A. V. Handbook of Integral Equations, 2nd ed., Chapman & Hall/CRC, Boca Raton (2008)
[41] LIM, C. W. and YANG, Y. Wave propagation in carbon nanotubes:nonlocal elasticity-included stiffness and velocity enhancement effects. Journal of Mechanics of Materials and Structures, 5(3), 459-476(2010)
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