[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/scs.2017.24.2.141

Free vibrations of fluid conveying microbeams under non-ideal boundary conditions

Atci, Duygu (Department of Mechanical Engineering, Manisa Celal Bayar University)
Bagdatli, Suleyman Murat (Department of Mechanical Engineering, Manisa Celal Bayar University)

Publication Information

Steel and Composite Structures / v.24, no.2, 2017 , pp. 141-149 More about this Journal

Abstract

In this study, vibration analysis of fluid conveying microbeams under non-ideal boundary conditions (BCs) is performed. The objective of the present paper is to describe the effects of non-ideal BCs on linear vibrations of fluid conveying microbeams. Non-ideal BCs are modeled as a linear combination of ideal clamped and ideal simply supported boundary conditions by using the weighting factor (k). Non-ideal clamped and non-ideal simply supported beams are both considered to show the effects of BCs. Equations of motion of the beam under the effect of moving fluid are obtained by using Hamilton principle. Method of multiple scales which is one of the perturbation techniques is applied to the governing linear equation of motion. Approximate solutions of the linear equation are obtained and the effects of system parameters and non-ideal BCs on natural frequencies are presented. Results indicate that, natural frequencies of fluid conveying microbeam changed significantly by varying the weighting factor k. This change is more remarkable for clamped microbeams rather than simply supported ones.

Keywords

microsystems; vibration; non-ideal boundary conditions; perturbation methods;

Citations & Related Records

Times Cited By KSCI : 4 (Citation Analysis)

Reference
Cited By KSCI

1	Mindlin, R.D. (1964), "Micro-structure in linear elasticity", Archive Rational Mech. Analy., 16(1), 51-78. DOI
2	Mindlin, R.D. and Tiersten, H.F. (1962), "Effects of couple stresses in linear elasticity", Arch. Ration. Mech. Anal., 11(1), 415-448. DOI
3	Nayfeh, A.H. (1981), Introduction to Perturbation Techniques, John Wiley & Sons, USA.
4	Ni, Q., Zhang, Z.L. and Wang, L. (2011), "Application of the differential transformation method to vibration analysis of pipes conveying fluid", Appl. Math. Comp., 217(16), 7028-7038. DOI
5	Paidoussis, M.P. and Li, G.X. (1993), "Pipes conveying fluid: A model dynamical problem", J. Fluids Struct., 7(2), 137-204. DOI
6	Paidoussis, M.P., Semler, C., Wadham-Gagnon, M. and Saaid, S. (2007), "Dynamics of cantilevered pipes conveying fluid. Part 2: Dynamics of system with intermediate spring support", J. Fluids Struct., 23(4), 569-587. DOI
7	Pakdemirli, M. and Boyaci, H. (2001), "Vibrations of a stretched beam with non-ideal boundary conditions", Math. Comp. Appl., 6(3), 217-220.
8	Pakdemirli, M. and Boyaci, H. (2002), "Effect of non-ideal boundary conditions on the vibrations of continuous systems", J. Sound Vib., 249(4), 815-823. DOI
9	Pakdemirli, M. and Boyaci, H. (2003), "Non-linear vibrations of a simple-simple beam with a non-ideal support in between", J. Sound Vib., 268, 331-341. DOI
10	Park, S.K. and Gao, X-L. (2006), "Bernoulli-Euler beam model based on a modified couple stress theory", J. Micromech. Microeng., 16(11), 2355-2359. DOI
11	Thurman, A.L. and Mote, C.D. (1969), "Free, periodic, nonlinear oscillations of an axially moving strip", J. Appl. Mech., 36, 3.
12	Toupin, R.A. (1962), "Elastic materials with couple-stresses", Arch. Ratio. Mech. Anal., 11(1), 385-414. DOI
13	Wang, L. (2010), "Size-dependent vibration characteristics of fluid-conveying micro tubes", J. Fluids Struct., 26(4), 675-684. DOI
14	Wang, L. (2012), "Vibration analysis of nanotubes conveying fluid based on gradient elasticity theory", J. Vib. Control, 18(2), 313-320. DOI
15	Wang, L., Gan, J. and Ni, Q. (2013a), "Natural frequency analysis of fluid-conveying pipes in the ADINA system", J. Phys.: Conference Series, 448(1), 012014.
16	Wang, L., Liu, H.T., Ni, Q. and Wu, Y. (2013b), "Flexural vibrations of micro scale pipes conveying fluid by considering the size effects of micro-flow and micro-structure", Int. J. Eng. Sci., 71, 92-101. DOI
17	Yang, F., Chong, A.C.M., Lam, D.C.C. and Tong, P. (2002), "Couple stress based strain gradient theory for elasticity", Int. J. Solids Struct., 39(10), 2731-2743. DOI
18	Yin, L., Qian, Q. and Wang, L. (2011), "Strain gradient beam model for dynamics of microscale pipes conveying fluid", Appl. Math. Model., 35(6), 2864-2873. DOI
19	Yurddas, A., Ozkaya, E. and Boyaci, H. (2012), "Nonlinear vibrations and stability analysis of axially moving strings having non-ideal mid-support conditions", J. Vib. Control, 20(4), 518-534. DOI
20	Yurddas, A., Ozkaya, E. and Boyaci, H. (2013), "Nonlinear vibrations of axially moving multi-supported strings having non-ideal support conditions", Nonlin. Dyn., 73(3), 1223-1244. DOI
21	Stolken, J.S. and Evans, A.G. (1998), "Microbend test method for measuring the plasticity length scale", Acta Materialia, 46(14), 5109-5115. DOI
22	Bagdatli, S.M. and Uslu, B. (2015), "Free vibration analysis of axially moving beam under non-ideal conditions", Struct. Eng. Mech., Int. J., 54(3), 597-605. DOI
23	Zeighampour, H. and Tadi Beni, Y. (2014), "Size-dependent vibration of fluid-conveying double-walled carbon nanotubes using couple stress shell theory", Physica E, 61, 28-39. DOI
24	Akgoz, B. and Civalek, O. (2013a), "Buckling analysis of linearly tapered micro-columns based on strain gradient elasticity", Struct. Eng. Mech., Int. J., 48(2), 195-205. DOI
25	Akgoz, B. and Civalek, O. (2013b), "Free vibration analysis of axially functionally graded tapered Bernoulli-Euler microbeams based on the modified couple stress theory", Compos. Struct., 98, 314-322. DOI
26	Akgoz, B. and Civalek, O. (2015a), "A novel microstructuredependent shear deformable pipes conveying fluid", Int. J. Mech. Sci., 99, 10-20. DOI
27	Akgoz, B. and Civalek, O. (2015b), "Bending analysis of FG microbeams resting on Winkler elastic foundation via strain gradient elasticity", Comp. Struct., 134, 294-301. DOI
28	Akgoz, B. and Civalek, O. (2016), "Bending analysis of embedded carbon nanotubes resting on an elastic foundation using strain gradient theory", Acta Astronautica, 119, 1-12. DOI
29	Ansari, R., Gholami, R., Norouzzadeh, A. and Sahmani, S. (2015), "Size-dependent vibration and instability of fluid-conveying functionally graded microshells based on the modified couple stress theory", Microfluid. Nanofluid., 19(3), 509-522. DOI
30	Atci, D. and Bagdatli, S.M. (2017), "Vibrations of fluid conveying microbeams under non-ideal boundary conditions", Microsyst. Technol., 1-12. DOI: 10.1007/s00542-016-3255-y DOI
31	Chong, A.C.M. and Lam, D.C.C. (1999), "Strain gradient plasticity effect in indentation hardness of polymers", J. Materials Res., 14(10), 4103-4110. DOI
32	Bagdatli, S.M., Ozkaya, E. and Oz, H.R. (2013), "Dynamics of axially accelerating beams with multiple supports", Nonlin. Dyn., 74(1-2), 237-255. DOI
33	Baohui, L., Hangshan, G., Yongshou, L. and Zhufeng, Y. (2012), "Free vibration analysis of micro pipe conveying fluid by wave method", Results Physics, 2, 104-109. DOI
34	Chakraborty, G., Mallik, A.K. and Hatwal, H. (1998), "Non-linear vibration of a travelling beam", Int. J. Nonlin. Mech., 34(4), 655-670.
35	Ding, H. and Chen, L. (2011), "Natural frequencies of nonlinear vibration of axially moving beams", Nonlin. Dyn., 63(1), 125-134. DOI
36	Ekici, H.O. and Boyaci, H. (2007), "Effects of non-ideal boundary conditions on vibrations of micro beams", J. Vib. Control, 13(9-10), 1369-1378. DOI
37	Ellis, S.R.W. and Smith, C.W. (1968), "A thin plate analysis and experimental evaluation of couple stress effects", Exper. Mech., 7(9), 372-380. DOI
38	Fleck, N.A., Muller, G.M., Ashby, M.F. and Hutchinson, J.W. (1994), "Strain gradient plasticity: theory and experiment", Acta Metall. Mater., 42(2), 475-487. DOI
39	Hosseini, M. and Bahaadini, R. (2016), "Size dependent stability analysis of cantilever micro-pipes conveying fluid based on modified strain gradient theory", Int. J. Eng. Sci., 101, 1-13. DOI
40	Ibrahim, R.A. (2010), "Overview of mechanics of pipes conveying fluids-Part I: Fundamental studies", J. Press. Vessel Tech., 132(3), 034001. DOI
41	Ibrahim, R.A. (2011), "Mechanics of pipes conveying fluids-Part II: Applications and fluid elastic problems", J. Pressure Vessel Tech., 133(2), 024001. DOI
42	Kural, S. and Ozkaya, E. (2015), "Size-dependent vibrations of a micro-beam conveying fluid and resting on an elastic foundation", J. of Vib. Cont., 23(7), 1106-1114. DOI: 10.1177/1077546315589666. DOI
43	Kesimli, A., Ozkaya, E. and Bagdatli, S.M. (2015), "Nonlinear vibrations of spring-supported axially moving string", Nonlin. Dyn., 81(3), 1523-1534. DOI
44	Kong, S., Zhou, S., Nie, Z. and Wang, K. (2008), "The sizedependent natural frequency of Bernoulli-Euler micro-beams", Int. J. Eng. Sci., 46(5), 427-437. DOI
45	Kural, S. and Ozkaya, E. (2012), "Vibrations of an axially accelerating, multiple supported flexible beam", Struct. Eng. Mech., Int. J., 44(4), 521-538. DOI
46	Lam, D.C.C., Yang, F., Chong, A.C.M., Wang, J. and Tong, P. (2003), "Experiments and theory in strain gradient elasticity", J. Mech. Phys. Solids, 51(8), 1477-1508. DOI
47	Lee, J. (2013), "Free vibration analysis of beams with non-ideal clamped boundary conditions", J. Mech. Sci. Tech., 27(2), 297-303. DOI
48	Li, L., Hu, Y., Li, X. and Ling, L. (2016), "Size-dependent effects on critical flow velocity of fluid-conveying microtubes via nonlocal strain gradient theory", Microfluidics and Nanofluidics, 20(5), 76. DOI
49	Ma, Q. and Clarke, D.R. (1995), "Size dependent hardness of silver single crystals", J. Materials Res., 10(04), 853-863. DOI
50	Ma, H.M., Gao, X-L. and Reddy, J.N. (2008), "A microstructuredependent Timoshenko beam model based on a modified couple stress theory", J. Mech. Phys. Solids, 56(12), 3379-3391. DOI
51	McFarland, A.W. and Colton, J.S. (2005), "Role of material microstructure in plate stiffness with relevance to microcantilever sensors", J. Micromech. Microeng., 15(5), 1060-1067. DOI